Pellet Mill For Sale Canada

This is probably the first question we get from anyone looking at a pellet mill for sale Canada. The answer isn’t one-size-fits-all—it depends entirely on what you’re processing and how much you need to produce. Over the years, we’ve dialed in the right configurations for wood, feed, forage, fertilizer, and even specialty materials like cat litter. Here’s a breakdown of the main series we ship north and what you can expect in terms of specs and investment.

Feed Pellet Mills (SZLH Series)

For poultry, swine, cattle, and aquaculture feed operations across Ontario, Quebec, and Alberta, the SZLH series is our most requested. These are ring die mills built for consistent pellet durability and high throughput.

The line starts with the SZLH250 small animal feed pellet machine—a 22kW unit pushing 1-1.5 t/h, suitable for smaller farms or starter operations. Move up to the SZLH320 (37kW, 3-4 t/h) and SZLH350 (55kW, 5-6 t/h), which are common in mid-size feed mills. The larger end of the range—SZLH420 (110kW, 10-12 t/h) up to the SZLH768 (315kW, 38-40 t/h)—is what you’ll find in commercial feed plants in Canada supplying regional markets.

All models in this series include a feeder (1.1-2.2kW depending on size) and conditioner (1.5-11kW) for steam treatment. Die diameter ranges from 250mm to 762mm, and pellet size is adjustable from 2mm to 12mm.

When Canadian customers ask about feed pellet machine price in Canada, we usually give them a range. A basic SZLH250 starter setup runs around $6,500-$8,500 USD. The mid-range SZLH320 typically lands between $15,000-$18,000, while a complete SZLH350 with controls is often in the $26,000-$32,000 range. Commercial-scale units like the SZLH420 can go from $28,000-$35,000, and the larger industrial models—SZLH508 through SZLH768—range from $40,000 up to $85,000 depending on configuration.

Wood Pellet Mills (MZLH Series)

For sawmill residuals, forestry waste, and clean wood processing, the MZLH series is built differently than feed mills. These units come with anti-arching feeders and force feeders to handle the lighter bulk density of wood fiber. The smallest in this line—the MZLH320 (22kW) small wood pellet machine—does about 0.2-0.3 t/h, which is a good entry point for someone testing the market with shavings from their own mill. The MZLH350 (37kW, 0.3-0.5 t/h) is another starter option.

Most commercial wood pellet operations we’ve supplied in British Columbia and Quebec go with larger models. The MZLH420 (90kW, 1.0-1.2 t/h) and MZLH520 (132kW, 1.5-2.0 t/h) are common for mid-size producers. The MZLH678 (185kW, 2.5-3.0 t/h) and MZLH768 (250kW, 3.0-4.0 t/h) are what you see in biomass pellet mills in Canada running 20-hour days.

For anyone checking pellet machine price in Canada for wood applications, here’s the typical range. The MZLH320 starter mill goes for about $14,000-$17,000. The MZLH350 is in the $19,000-$23,000 range. The MZLH420—probably the most popular starter size for commercial operations—typically runs $27,000-$32,000. The MZLH520 is around $42,000-$48,000. Larger industrial units like the MZLH678 and MZLH768 fall between $62,000-$75,000 and $75,000-$88,000 respectively.

If you’re asking about small wood pellet machine price in Canada, the MZLH320 or MZLH350 are where you’d start. Both are under $25,000, which makes them accessible for farmers, small sawmills, or anyone wanting to process their own wood waste.

Straw & Forage Pellet Mills (CZLH Series)

Alfalfa, timothy, canola straw, and mixed hay require a different approach than wood or grain. The CZLH series is designed with anti-arching feeders and conditioners to handle the fibrous, sometimes dusty nature of forage materials. These units are popular in Saskatchewan and Alberta where forage production is concentrated.

The CZLH250 (22kW) is the smallest in this family, doing about 0.3-0.5 t/h—good for smaller farms or custom processing. The CZLH320 (22kW, 0.5-1.0 t/h) and CZLH350 (37kW, 1.0-1.5 t/h) are common for mid-scale operations. Commercial forage pellet producers typically go with the CZLH420 (90kW, 1.8-2.0 t/h), CZLH520 (132kW, 2.8-3.0 t/h), or the larger CZLH678 (185kW, 4-5 t/h) and CZLH768 (250kW, 6-8 t/h).

For customers looking at grass pellet machine price in Canada, the CZLH250 starter unit runs about $7,000-$9,000. The CZLH320 is typically $18,000-$22,000, and the CZLH350 falls around $23,000-$27,000. The CZLH420 is in the $28,000-$34,000 range, while the larger CZLH520, CZLH678, and CZLH768 range from $48,000-$58,000, $68,000-$80,000, and $80,000-$95,000 respectively.

If you’re pricing a small pellet machine price in Canada for grass or straw, the CZLH250 or CZLH320 are your entry points.

Cat Litter Pellet Mills (MSZLH Series)

This is a more specialized application, but we’ve seen steady demand from operations using okara (tofu byproduct) or recycled paper. The MSZLH series uses the same basic architecture as the SZLH feed mills but with stainless steel dies and contact surfaces to handle the acidity and moisture of these non-traditional materials. Capacities mirror the SZLH line—from the MSZLH250 (22kW, 1.0-1.5 t/h) up to the MSZLH768 (315kW, 38-40 t/h).

Pricing for cat litter mills follows similar ranges as the feed mills, but stainless steel components add about 15-20% to the base cost.

Fertilizer Pellet Mills (FZLH Series)

For poultry litter, cattle manure, compost, and other organic fertilizers, the FZLH series is built with anti-arching feeders and force feeders to handle materials that are denser and sometimes stickier than wood or feed. These are common in operations across the Fraser Valley, Ontario, and Alberta where livestock operations are looking to monetize manure.

The FZLH250 (22kW, 1.0-1.5 t/h) is the smallest, suitable for smaller farms. The FZLH320 (22kW, 2-3 t/h) and FZLH350 (37kW, 3-5 t/h) are common mid-size units. Commercial fertilizer producers typically go with the FZLH420 (90kW, 6-8 t/h), FZLH520 (132kW, 9-12 t/h), or the larger FZLH678 (185kW, 18-22 t/h) and FZLH768 (250kW, 22-26 t/h).

The pellet mill for sale Canada in this category ranges from about $7,000-$9,000 for the FZLH250 small fertilizer pellet machine, up to $18,000-$22,000 for the FZLH320, and $28,000-$34,000 for the FZLH350. The FZLH420 typically runs $35,000-$42,000, while larger units like the FZLH520, FZLH678, and FZLH768 fall between $55,000-$68,000, $80,000-$95,000, and $95,000-$115,000.

What About Small Starter Mills?

We get a lot of calls from Canadian producers who want to test the market before committing to a large line. If you’re searching for small feed pellet machine price in Canada, the SZLH250 or SZLH320 are where you start—both under $20,000 for the machine itself. For small pellet machine price in Canada in general, the MZLH320 (wood), CZLH250 (forage), or FZLH250 (fertilizer) are all under $20,000, with the CZLH250 being the most affordable around $7,000-$9,000.

If you’re specifically looking at small wood pellet machine price in Canada, the MZLH320 at $14,000-$17,000 is the most common entry point. We’ve had customers start with that, prove the market, and then add larger mills later—sometimes keeping the small unit for specialty runs or backup.

A Note on Pricing and Customization

The numbers above are ballpark FOB Qingdao ranges for the base machine with standard components. But here’s the thing—most of the pellet mill in Canada projects we do aren’t just single machines. They include custom feeders, conditioners, dies sized for specific raw materials, and sometimes full control panels. All those add-ons affect the final cost of pellet mill for sale Canada.

Also, what you see above is our main series, but not everything we offer. We’ve built custom configurations for materials ranging from shrimp feed to biochar to pest control baits. If your raw material doesn’t fit neatly into one of these categories, we’ll figure out the right die metallurgy, conditioning setup, and feed system to make it work.

We get this question a lot from aquaculture operations across Canada—salmon farms in BC, trout hatcheries in Ontario, and shrimp operations in New Brunswick. When someone asks about floating fish feed machine price in Canada, they’re rarely asking about just the extruder.

A complete line includes grinding, mixing, extrusion, drying, coating, and cooling. Here’s what those systems typically run, based on the lines we’ve installed over the past few years.

Single-Screw Extruder Lines

Single-screw extrusion is a solid choice for many Canadian aquaculture operations, especially when you’re producing sinking feed or moderate-expansion floating feed. The technology is simpler, maintenance costs are lower, and for operations under 1,000 kg/h, it’s often the more economical route.

For a fish feed extruder in Canada with single-screw configuration, here’s what a complete floating fish feed production line—including hammer mill, mixer, extruder, belt dryer, coater, and cooler—typically runs:

• 200-400 kg/h line: This size works well for smaller hatcheries or farms with 500,000 to 1 million fish in production. The complete setup usually lands between $60,000 and $80,000 USD. We’ve installed this size for a trout operation in Ontario that wanted to bring feed production in-house. They run it about 20 hours a week and produce enough for their own needs plus a small wholesale market.
• 500-600 kg/h line: This is a common size for mid-size aquaculture operations—think 2-3 million fish in rotation. The line runs around $70,000 to $100,000 USD. A salmon smolt producer on Vancouver Island went with this capacity. They needed consistent floating feed for their grow-out phase, and the single-screw extruder gives them enough control over expansion without the complexity of a twin-screw.
• 800-1,000 kg/h line: This capacity is where you start seeing commercial-scale operations. The complete aquafeed pellet mill in Canada line in this range typically costs $130,000 to $170,000 USD. A tilapia operation in southern Ontario installed one of these recently. They’re producing about 600 tons annually and selling to other farms in the region.

Single-screw lines are also suitable for sinking fish feed pellet mill in Canada applications. If you’re producing feed for species that feed at the bottom—like sturgeon or certain marine fish—the lower expansion ratio of single-screw is actually preferable.

Twin-Screw Extruder Lines

When you need more control over expansion, higher throughput, or the ability to switch between floating and sinking formulations, twin-screw extrusion is the way to go. Twin-screw systems are more expensive upfront, but they offer better texture control, higher oil inclusion rates, and the flexibility to run a wider range of formulas.

For a floating fish feed extruder in Canada with twin-screw configuration, here’s what complete production lines run:

• 0.5-1.0 t/h line: This is the entry point for commercial twin-screw systems. Complete lines—with grinding, batching, mixing, the extruder itself, belt dryer, coating drum, and cooling—typically fall between $150,000 and $200,000 USD. We’ve installed this capacity for a few smaller salmon farms in BC that wanted to produce their own starter feeds. The flexibility to adjust pellet size and expansion as fish grow is a big advantage.
• 1.5-2.0 t/h line: This is a popular size for mid-size salmon feed pellet mills in Canada. The complete system runs about $440,000 to $560,000 USD. One operation on Vancouver Island runs this capacity for their grower feeds. They produce about 3,000 tons annually and have been able to cut feed costs by about 25% compared to imported product.
• 3.0-4.0 t/h line: This capacity is where you get into serious commercial production. Complete aquaculture feed production line in Canada systems in this range cost between $530,000 and $650,000 USD. A trout operation in Quebec upgraded to this size a couple of years ago. They supply feed to about a dozen smaller farms across the province.
• 5.0-6.0 t/h line: This is industrial-scale production. Complete lines run $670,000 to $840,000 USD. These are the kinds of systems you’d find in a dedicated feed plant in Canada serving a regional aquaculture industry. The automation level is high—batching systems, moisture control, and real-time monitoring of expansion rates.
• 8.0-10.0 t/h line: This is large-scale commercial production. Complete lines fall between $880,000 and $1,200,000 USD. We’ve supplied this capacity for a feed manufacturer in New Brunswick serving the Atlantic salmon industry. The line includes twin-screw extrusion with multiple die options, a multi-pass belt dryer, and a coating system for oil and attractants.

For larger capacities beyond 10 t/h, we custom-engineer systems based on the specific requirements. Every line is different once you get into that scale.

What’s Included in These Prices?

When someone asks about fish feed making machine in Canada pricing, they need to know what’s actually in the package. The ranges above cover complete production lines including:

• Raw material receiving and cleaning (magnetic separators, screens)
• Hammer mill or fine grinding system
• Batching scale and mixer (ribbon or paddle, depending on formulation)
• Conditioner and extruder (single or twin-screw, with die sets)
• Belt dryer or fluid bed dryer (multi-zone for moisture control)
• Coating drum for fat and liquid applications
• Cooler and screener
• Control panel with PLC

These are FOB Qingdao ranges. Shipping to Canadian ports, installation, and commissioning are additional. Some customers handle installation themselves; others want our team on-site. That’s something we quote case by case.

Species-Specific Considerations

Not all fish feed is the same. If you’re looking for a tilapia feed pellet mill in Canada, the equipment needs differ from a salmon feed pellet mill in Canada. Tilapia feed typically requires higher starch gelatinization and more expansion. Salmon feed needs high oil inclusion and dense pellets that don’t disintegrate in saltwater. Trout feed pellet mill in Canada applications often fall somewhere in between.

For shrimp feed pellet mill in Canada or shrimp feed extruder in Canada applications, you’re usually looking at smaller-diameter pellets (2mm or less) that sink immediately. Shrimp feed also requires fine grinding—often through a 0.8mm screen—which means more horsepower in the grinding stage. We’ve done a few of these for operations in New Brunswick and the pricing aligns with the lower end of the twin-screw ranges because the throughput is usually in the 0.5-1.0 t/h range.

A Note on the Numbers

The ranges above are based on real projects we’ve shipped to Canadian aquaculture operations. But here’s the thing—every line is slightly different. Die selection, dryer configuration, automation level, and whether you need stainless steel contact surfaces all affect the final price of pellet mill for sale Canada when we’re talking about full extrusion lines.

Also, what’s listed above is our main extruder line configurations, but not everything we offer. We’ve built custom systems for everything from marine shrimp to sturgeon to ornamental fish feed. If your target species isn’t listed, we’ve probably built a fish feed production plant for it somewhere.

When Canadian livestock operations start looking at bringing feed production in-house, the first question is always about investment. Whether you’re running a poultry operation in Ontario, a feedlot in Alberta, or a hog barn in Manitoba, the cost of a feed pellet production line in Canada varies wildly based on capacity, automation level, and whether you need mash-only or full pelleting capability. Here’s what we’ve learned from installing these lines across the country.

Small-Scale Lines: Flat Die Systems

For smaller farms, starter operations, or anyone wanting to test the market before committing to a larger investment, flat die systems make sense. These lines are compact, easier to operate, and give you the flexibility to produce both mash feed and pellets from the same equipment.

A complete animal feed processing line in Canada with flat die configuration includes a hammer mill for grinding grains, a horizontal mixer for blending ingredients, and the flat die pellet machine itself. The capacity splits are interesting—you can run mash feed at higher rates while producing pellets at a lower rate, which works well for farms that feed a mix of both.

• 1t/h mash + 0.2-0.3t/h pellet: This starter setup runs around $12,500 to $14,500 USD. Good for smaller poultry operations or hog farms with a few thousand head. You get the ability to grind your own grain, mix rations, and experiment with pelleting.
• 1t/h mash + 0.5-0.6t/h pellet: This line typically lands between $13,800 and $15,800 USD. We’ve installed this for a few mixed farms in Quebec that wanted to produce their own broiler feed. The extra pelleting capacity means they can pellet all their grower rations while still using mash for starter diets.
• 1t/h mash + 0.8-1.0t/h pellet: The largest of the flat die systems runs about $14,800 to $17,000 USD. At this capacity, you’re approaching the output of small ring die systems. A layer operation in British Columbia uses one of these—they pellet about 70% of their feed and sell the excess to neighboring farms.

For anyone searching for feed mill equipment for sale Canada at the entry level, these flat die lines are where you start. They’re not going to run 24/7, but for a farm with 5,000-10,000 birds or a few hundred head of cattle, they do the job.

Commercial-Scale Lines: Ring Die Systems

Once you get past about 1 t/h, you’re looking at ring die systems. These are what you’d find in dedicated feed plants in Canada serving regional livestock operations. Ring die lines include weighing systems, hammer mills or roller mills, mixers, conditioners, pellet mills, coolers, and sometimes crumbling rolls and coating systems.

The price range for these systems is wide because the configuration can vary so much. A basic line with manual controls and minimal automation costs less than a fully automated line with PLC, recipe management, and integrated reporting. Here’s what the ranges look like based on what we’ve shipped to Canadian operations:

• 1-2 t/h lines: These run from $30,000 to $60,000 USD. Suitable for mid-size poultry farms, smaller feedlots, or operations looking to replace purchased feed with in-house production. One hog operation in Manitoba runs a 1.5 t/h small scale feed mill and covers their own finishing rations plus feed for a few contract growers.
• 3-4 t/h lines: These fall between $60,000 and $200,000 USD. The wide range reflects automation level. A basic 3 t/h poultry feed pellet line in Canada with manual controls is on the lower end; a fully automated 4 t/h line with fat coating and crumbling rolls pushes toward the higher end. We’ve installed several of these for layer operations in Ontario and broiler farms in Quebec.
• 5-6 t/h lines: These run $80,000 to $250,000 USD. This capacity is common for commercial pig feed manufacturing plants in Canada. One operation in southern Ontario runs a 5 t/h line producing nursery, grower, and finisher rations for about 15,000 head. The line includes a batching system, roller mill, twin-shaft paddle mixer, and a cooler.
• 10 t/h lines: These range from $170,000 to $320,000 USD. At this capacity, you’re into regional commercial production. A cattle feed processing machinery in Canada installation in Alberta runs at this rate, producing finishing rations for feedlots within a 200km radius. The line includes full automation, multiple ingredient bins, and a steam conditioning system with precise temperature control.
• 15 t/h lines: These run $240,000 to $400,000 USD. This is where you start seeing dedicated livestock feed mill equipment in Canada serving a wider market. A cooperative in Saskatchewan uses a 15 t/h line to produce feed for their member farms. The system includes a receiving pit, bucket elevators, and automated batching with formulation software.
• 20 t/h lines: These fall between $440,000 and $600,000 USD. This capacity is typical for industrial feed production equipment in Canada supplying multiple large operations. A feed mill in Quebec runs a 20 t/h line producing both poultry and dairy rations. They have separate batching and mixing lines feeding into a common pelleting section.
• 30 t/h lines: These run $600,000 to $700,000 USD. At this scale, you’re looking at feed plant machinery in Canada that runs 24/7. The line includes redundant equipment—backup hammer mills, multiple pellet mills—so production continues during maintenance.
• 40 t/h lines: These range from $700,000 to $800,000 USD. This is large-scale commercial production serving hundreds of farms. We’ve installed a few of these for major feed manufacturers in Alberta and Ontario. The control rooms look like something out of a refinery—multiple screens, real-time monitoring, automated sampling.
• 60 t/h lines and above: These exceed $1,100,000 USD, with 120 t/h systems going significantly higher. At this scale, every line is custom-engineered. We’ve done projects where the customer wanted specific hammer mill configurations, specialized die metallurgy for high-fiber rations, and integration with existing grain handling systems.

What Affects the Price?

When someone asks about animal feed production plant for sale Canada pricing, they need to understand why the ranges are so wide. Same capacity, completely different price. Here’s what moves the needle:

• Automation level: A manual line with push-button controls costs far less than a PLC-controlled system with recipe storage, automated batching, and remote monitoring.
• Ingredient handling: If you’re storing grain in bags, you need less equipment than if you’re receiving by truck and using multiple bins. We’ve done projects where the ingredient handling system cost as much as the pelleting section.
• Pellet quality requirements: Some customers need 90% pellet durability; others are fine with 75%. Tighter specs mean better conditioners, more precise die selection, and sometimes post-pelleting coating systems.
• Building integration: Lines designed to fit into existing buildings cost differently than greenfield installations where we design the whole facility layout.

A Note on What’s Included

The ranges above are for complete ring die animal feed machinery Canada lines—from ingredient receiving to finished product storage. That includes the weighing system, hammer mills or roller mills, mixers, conditioners, pellet mill, cooler, screener, and control system. Shipping, installation, and commissioning are separate.

Also worth noting—these are our standard configurations, but not everything we offer. We’ve built feed factory setup in Canada projects for everything from organic feed to medicated rations to custom blends for specialty livestock. If your operation has specific requirements—like allergen separation, liquid addition systems, or integration with existing grain dryers—we can build that.

Need a Quote for Your Operation?

The numbers above are reference ranges based on actual installations. But every feed plant engineering in Canada project is different. Your raw material mix, target pellet quality, available building space, and automation preferences all affect the final feed processing machine for sale Canada price.

Tell us what you’re feeding—poultry, swine, cattle, or something else—and what your target annual tonnage is. We’ll put together a custom proposal with actual numbers based on lines we’ve installed in similar Canadian operations.

If you’re processing forage—alfalfa, timothy, wheat straw, canola straw—for livestock feed or pellet production, the hammer mill is where it all starts. Get the grinding wrong and the rest of your line suffers. We’ve supplied these SFSP series hammer mills to forage operations across Alberta, Saskatchewan, Manitoba, and Quebec. Here’s what you need to know about sizing, capabilities, and what a straw hammer mill in Canada actually costs.

SFSP56*40 – Entry-Level Forage Grinder

This is the smallest in the line, with a 560mm rotor diameter and 400mm crushing chamber width. Rotor speed is 2980 rpm, hammer tip speed hits 88 m/s. Powered by a 37kW motor, it handles 0.8-1.0 t/h of grass or straw.

For a small farm operation—say, a mixed farm in Ontario with a few hundred head of cattle or a forage processing side business—this size works. It’s what we typically recommend when someone asks about a grass grinding machine in Canada for starter operations. The machine will take material up to 5cm and grind it down to whatever screen size you need, from 0.5mm up to 20mm.

Price range for this straw crusher machine Canada model: approximately $12,000 to $16,000 USD, depending on screen configuration and whether you need additional safety features like magnetic separators.

SFSP66*60 – Mid-Size Forage Mill

Stepping up to the 660mm rotor diameter models. The SFSP66*60 has a 600mm crushing chamber width and runs at 2980 rpm. Hammer tip speed increases to 103 m/s, which gives you finer grinding with the same rotor speed. Power options are 55kW or 75kW depending on your material.

Throughput for straw and grass runs 1.0-1.5 t/h with the 55kW motor. If you upgrade to 75kW, you can push higher—closer to 2.0-2.5 t/h depending on moisture and screen size.

This is a common size for hay grinding mill in Canada installations serving mid-size feedlots or forage pellet operations. We’ve installed a few of these in southern Alberta for operations processing alfalfa for dairy rations. The 660mm rotor diameter gives you more grinding surface than the smaller model, which matters when you’re running high-fiber material.

Price range: $18,000 to $28,000 USD. The spread depends on motor size and whether you want a heavier-duty rotor configuration for abrasive materials like canola straw.

SFSP66*80 – Commercial-Scale Grinder

This model has an 800mm crushing chamber width and runs on 75kW, 90kW, or 110kW motors. Throughput for grass and straw hits 2.0-2.5 t/h on the lower end and can push 3.0-4.0 t/h with the larger motor.

If you’re building a grass hammer mill for feed production in Canada at commercial scale, this is where you start. One forage operation in Saskatchewan runs this model with a 90kW motor, processing about 2.5 t/h of wheat straw for bedding pellets. They run it about 1,500 hours a year and have been through three sets of screens in five years—reasonable wear for the material.

Price range: $22,000 to $38,000 USD. The higher end includes heavier-duty hammers and screens designed for abrasive grasses like canola or flax straw. Those crops have higher silica content and wear standard hammers faster.

SFSP66*100 – High-Volume Processing

Chamber width expands to 1000mm on this model. Motor options: 110kW, 132kW, or 160kW. Throughput for grass and straw ranges from 3.0-4.0 t/h up to about 5.0 t/h depending on material and screen size.

This is what you’d find in a dedicated forage hammer mill in Canada setup serving regional pellet producers. We installed one of these for a cooperative in Manitoba that processes a mix of alfalfa, timothy, and brome grass into horse feed pellets. They run it about eight hours a day during their processing season. The 1000mm chamber width means you can feed material faster without bogging down the rotor.

Price range: $32,000 to $52,000 USD. The variability comes from motor selection and whether you need a heavier rotor assembly for continuous operation.

SFSP66*120 – Industrial Scale

Chamber width at 1200mm, motor options from 160kW to 185kW. Throughput hits 5.0-6.0 t/h on grass and straw, though you can push higher with finer screens depending on the material.

This is the kind of industrial grass grinding machine in Canada you’d see at a large feed mill or commercial pellet plant. A feedlot in Alberta uses one of these to grind wheat straw for their finishing rations. They run it about 12 hours a day during peak feeding season. The wider chamber means they can feed round bales through a bale breaker without choking the mill.

Price range: $48,000 to $68,000 USD. At this scale, we usually include a heavier-duty bearing assembly and upgraded hammer tips as standard.

SFSP66*150 – Heavy-Duty Production

The largest in the line. 1500mm crushing chamber width. Motor options: 220kW and up. Throughput for grass and straw hits 7.0-8.0 t/h consistently, and with the right screen configuration you can push higher.

If you’re operating a grass straw hammer mill in Canada at this scale, you’re likely supplying multiple pellet plants or running a large feed operation. We’ve installed these for a few major forage processors in Saskatchewan that export alfalfa pellets to Asia. The machine runs 20 hours a day during their processing window, and they keep a full set of spare screens and hammers on hand.

Price range: $72,000 to $95,000 USD. The high end includes automated screen change systems and heavier rotor balancing for continuous high-speed operation.

What These Prices Include

When we quote a grass hammer mill Canada price, it’s for the complete unit: rotor assembly, hammers, screens (one set of your specified size), motor, and control starter. These are FOB Qingdao ranges. Shipping to Canadian ports, customs clearance, and installation are additional.

The numbers above are for the SFSP series—what we call the drop-shaped hammer mill. The design improves airflow and reduces dead spots where material can accumulate. That matters when you’re processing fluffy stuff like straw or hay.

What Affects the Price?

If you’re comparing hay hammer mill in Canada prices, here’s what moves the needle beyond just the model size:

• Screen size: Finer screens (0.5-2mm) require more horsepower to push material through. If you’re grinding for fish feed or fine mash, you’ll need a larger motor than if you’re just breaking material down to 6-8mm for pelleting.
• Material type: Alfalfa grinds differently than wheat straw. Canola straw is more abrasive. If you’re processing high-silica materials, we recommend upgraded hammer metallurgy and wear plates. That adds 10-15% to the base price but pays for itself in reduced maintenance.
• Feed system: If you’re feeding baled material directly, you’ll need a bale breaker or an auger system sized to match the hammer mill’s intake. Some customers handle this separately; others want us to supply an integrated feed solution.

A Note on What These Machines Do

The SFSP series is designed to take material up to 5cm in size—so pre-chopped straw, hay that’s been through a bale processor, or forage that’s already been rough-cut. The hammer mill reduces it to whatever particle size you need for your next step. Swap the screen, change the particle size. That’s the flexibility these mills offer.

For anyone building a grass grinding machine for pellet plant in Canada operation, the hammer mill is often the bottleneck if it’s undersized. We see this a lot—someone specs a pellet mill that can do 3 t/h, then realizes their hammer mill can only feed it at 1.5 t/h. The SFSP line gives you room to match your pellet mill capacity.

Need a Quote for Your Operation?

The numbers above are reference ranges based on actual installations. But every forage feed hammer mill in Canada project is different. Your material type, target particle size, and operating hours all affect the final price.

Tell us what you’re grinding—alfalfa, wheat straw, mixed hay, something else—and what your target throughput is. We’ll recommend the right model and give you a custom quote based on what we’ve actually installed in similar Canadian forage operations.

When someone starts looking at a wood pellet plant in Canada, the first question is always investment. And the answer varies more than most people expect. A 0.5 t/h setup for a small sawmill in British Columbia costs a fraction of what a 20 t/h industrial plant serving the European export market requires. Based on the wood pellet lines we’ve installed across Canada—from small farm operations to major producers in Quebec and BC—here’s what you can expect to invest at different scales.

Entry-Level: Testing the Market (0.2-0.5 t/h)

For a small sawmill with sawdust piling up, or a farm operation looking to add value to wood waste, the starter sizes make sense. These lines are compact, require less building space, and let you prove the market before scaling up.

A pellet production line in Canada in the 0.2-0.3 t/h range typically runs between $20,000 and $140,000 USD. The wide spread reflects the difference between a bare-bones setup and a more automated line with proper drying and cooling. We’ve installed a 0.3 t/h line for a small mill in Ontario that wanted to bag pellets for local farm stores. They run it about 10 hours a week, and the equipment paid for itself in two seasons.

The 0.3-0.5 t/h lines fall between $28,000 and $160,000 USD. At this size, you’re looking at either a single MZLH350 pellet mill with supporting equipment, or a slightly larger MZLH420 with minimal automation. A sawmill operation in the Okanagan went with a 0.4 t/h line to process their own shavings into horse bedding pellets. They didn’t need a dryer—their sawdust was already kiln-dried—so the investment landed on the lower end of that range.

Small Commercial: 1-2 t/h

Once you’re producing more than a ton per hour, you’re entering small commercial territory. These lines are what you’d find serving local heating markets, greenhouse operations, or mid-size industrial customers.

A 1.0-1.2 t/h biomass pellet plant in Canada runs $39,000 to $220,000 USD. The spread here is about automation. A simple line with a single MZLH420 mill, basic dryer, and manual bagging sits at the lower end. A more automated line with a rotary dryer, cooler, screener, and PLC control pushes toward the higher end. We installed a 1.0 t/h line for a forestry cooperative in northern BC that processes logging slash. They went with the lower automation level and handle the line with two operators.

The 1.5-2.0 t/h range lands between $56,000 and $270,000 USD. At this capacity, you’re usually looking at a single MZLH520 or MZLH678 mill with a properly sized dryer. A pellet producer in Quebec runs a 1.8 t/h line processing mixed softwood from local sawmills. They sell about half their output to residential customers and half to a greenhouse operation. The investment landed around $180,000 for their complete line.

Mid-Size Commercial: 2.5-4 t/h

This is where wood pellet production starts to become a serious business. These lines are typically what you’d find supplying industrial contracts, export markets, or large regional distributors.

A 2.5-3.0 t/h biomass pellet manufacturing plant in Canada runs $78,000 to $350,000 USD. At this scale, you’re usually running a single MZLH678 or MZLH768 mill, or possibly two smaller mills in parallel for redundancy. The drying system needs to be properly sized—rotary dryer with enough capacity to handle wet chips coming in at 40-50% moisture. A facility in New Brunswick installed a 2.8 t/h line last year. They had existing building space and handled installation themselves, so their investment was in the lower half of that range.

The 3.0-4.0 t/h lines fall between $95,000 and $430,000 USD. This capacity typically requires a dedicated building, proper material handling equipment, and more sophisticated controls. A complete biomass pellet plant in Canada at this scale often includes a chip bin, magnet separator, hammer mill, rotary dryer with cyclone, the pellet mill itself, cooler, screener, and bagging system. We installed one of these for a forestry operation in Alberta that processes beetle-kill pine. They run about 16 hours a day during their production season.

Large-Scale Production: 5-8 t/h

At 5 t/h and above, you’re looking at industrial-scale production. These plants supply biomass power plants, large industrial boilers, and export containers.

A 5.0-6.0 t/h wood pellet plant equipment in Canada package runs $160,000 to $570,000 USD. At this scale, you’re typically running multiple pellet mills—often two MZLH768 units in parallel. The drying system needs to be robust, and you’ll likely have a dedicated receiving area for chips or sawdust. A producer in British Columbia installed a 5.5 t/h line a few years ago. They supply a local biomass power plant and have a container loading system for export. Their investment was around $420,000 for the complete system.

The 6.0-8.0 t/h range lands between $190,000 and $690,000 USD. This is where you start seeing serious automation—PLC-controlled systems with remote monitoring, automated die lubrication, and integrated quality control sampling. A facility in Quebec runs a 7 t/h line that operates 24 hours a day during winter months. They have three shifts of operators and a dedicated maintenance crew. Their investment was in the upper half of that range, with custom features for their specific raw material mix.

Industrial-Scale: 10-24 t/h

These are major industrial facilities. The kind of pellet factory in Canada that supplies multi-year contracts, exports by the shipload, and runs continuous operations.

A 10-12 t/h biomass pellet making plant in Canada runs $280,000 to $1,100,000 USD. At this scale, you’re talking about multiple large mills—often four MZLH768 units or a combination of larger models. The raw material handling system includes truck receiving pits, large storage bins, and automated reclaim systems. A producer in northern British Columbia installed a 10 t/h line to process sawmill residuals from a cluster of local mills. The investment was substantial, but they have long-term contracts with European buyers.

The 12-15 t/h range falls between $470,000 and $1,430,000 USD. A commercial pellet production line in Canada at this scale typically includes redundant equipment—backup mills, standby motors, and spare parts inventory. We’ve installed a couple of these for producers in Alberta and BC. One facility runs 20 hours a day, 340 days a year, with two full-time maintenance technicians on staff.

The 20-24 t/h range runs $570,000 to $2,100,000 USD. This is large-scale industrial production. The kind of automatic pellet production line in Canada that you’d find in major forest products regions. The control room looks like something out of a refinery. We’ve done a few at this scale, and every one is custom-engineered for the specific raw material supply chain and market requirements.

For capacities beyond 24 t/h, we custom-engineer each line based on the specific raw material, site conditions, and production targets. There’s no standard price range at that scale.

What’s Included in These Ranges?

When we quote a complete pellet production line in Canada, the package typically includes:

• Raw material receiving and storage (chip bins or silos)
• Cleaning equipment (magnetic separators, screens)
• Hammer mill or chipper for size reduction
• Rotary dryer with burner and cyclone
• Pellet mills (MZLH series, one or multiple units)
• Cooler (counterflow or vertical)
• Screener for fines removal
• Bagging or bulk loading system
• Control panel with PLC
• Dust collection system

These are FOB Qingdao ranges. Shipping to Canadian ports, customs clearance, installation, and commissioning are additional. Some customers handle installation themselves; others want our team on-site. That’s something we quote case by case.

What Affects the Price?

If you’re comparing industrial pellet plant in Canada prices, here’s what creates the wide ranges:

• Raw material type: Clean sawdust from a sawmill requires less preparation than logging slash or whole logs. If you’re chipping your own material, you’ll need more equipment upfront.
• Moisture content: Wet chips require larger dryers. If your raw material is already kiln-dried, you might skip the dryer entirely. That’s a $50,000-$150,000 difference depending on capacity.
• Automation level: A manual line with push-button controls costs less than a fully automated system with recipe management, remote monitoring, and automated die lubrication.
• Building integration: Lines designed to fit into existing buildings cost differently than greenfield installations where we design the whole facility layout.
• Pellet quality requirements: Industrial fuel pellets have different specs than residential heating pellets. Tighter durability requirements mean better coolers and more precise conditioning.

A Note on What These Prices Represent

The numbers above are based on actual installations we’ve done across Canada. But here’s the thing—every pellet processing plant in Canada is different. Your raw material supply, site conditions, target markets, and operating hours all affect the final investment.

Also, what’s listed above is our main line configurations, but not everything we offer. We’ve built custom biomass pelletizing plant equipment in Canada for everything from pelletized biochar to torrefied wood to specialty industrial fuels. If your raw material isn’t standard sawdust or wood chips, we’ve probably built a line for something similar somewhere.

If you’re growing alfalfa, timothy, mixed hay, or straw anywhere from British Columbia to Manitoba, you’ve probably thought about pelleting. The math is simple: pellets are denser than bales, easier to handle, and often command better prices. But the investment varies widely depending on whether you’re a small farm making feed for your own livestock or a commercial operation supplying the equine and dairy markets. Based on the forage lines we’ve installed across the Prairies and into Quebec, here’s what to expect.

Starter Operations: 0.3-2 t/h

This capacity range covers everything from a small farm testing the market to a mid-size operation producing feed for their own livestock. At this scale, you’re typically working with one or two CZLH pellet mills, a hammer mill sized to match, and basic support equipment.

A grass pellet production line in Canada in the 0.3-2 t/h range typically runs $37,000 to $62,000 USD. The spread depends on what you’re processing and how automated you want the line. On the lower end, we’ve installed a 0.5 t/h line for a mixed farm in Ontario that wanted to pellet their own hay for winter feeding. They already had a tractor and a bale processor, so the investment was just for the grinding and pelleting equipment.

On the higher end of this range, a 1.5 t/h line with a bale breaker, hammer mill, and properly sized cooler pushes closer to $60,000. A forage operation in Alberta went this route. They process a mix of alfalfa and timothy into 6mm horse feed pellets, selling to local stables and tack shops. The line runs about 20 hours a week during the off-season.

If you’re working with round bales, square bales, or loose hay, this scale handles all of them. The bale breaker at the front end needs to match your bale type—we’ve set up systems for both round and square configurations.

Mid-Size Commercial: 0.5-4 t/h

At this scale, you’re moving into commercial production. These lines are what you’d find supplying multiple farms, feed stores, or export contracts. The equipment list expands to include better material handling, more consistent drying, and often more automation.

A hay pellet production line in Canada in the 0.5-4 t/h range runs $80,000 to $200,000 USD. The wide spread reflects the difference between a basic line with manual controls and a more automated system with proper drying, cooling, and bagging.

We installed a 2 t/h line for a cooperative in Saskatchewan that processes alfalfa pellets for export to Asia. They went with a CZLH420 mill, a hammer mill sized for 4mm screen, a rotary dryer for the higher-moisture first-cutting hay, and a bagging line. Their investment landed around $140,000. They run the line about 1,500 hours a year and ship about 2,500 tons annually.

For operations processing straw—wheat or canola straw for bedding pellets or low-quality feed—the equipment is similar but the drying requirements are usually less. Straw often comes off the field at 12-14% moisture, so you can sometimes skip the dryer. That’s a $30,000-$50,000 savings depending on the system.

Commercial Production: 1-6 t/h

This is where you’re running a serious forage pelleting business. These lines typically have multiple mills, dedicated drying systems, and enough automation to run with minimal labor.

A straw pellet production line in Canada in the 1-6 t/h range runs $99,000 to $220,000 USD. At 3 t/h and above, you’re usually looking at a CZLH678 or CZLH768 as the core mill, sometimes two smaller mills in parallel for flexibility.

A forage processor in Quebec installed a 4 t/h line for processing timothy hay into export-grade horse pellets. Their line includes a bale breaker, hammer mill with 5mm screen, a belt dryer for gentle drying, the pellet mill, cooler, screener, and a bulk loading system. Investment was around $180,000. They run about 12 hours a day during their processing window and ship containers to the US and Europe.

If you’re processing alfalfa specifically, you need to consider the mineral content. Alfalfa has higher ash and silica than grass hay, which wears dies faster. A dedicated alfalfa pellet production line in Canada often includes dies with higher chromium content and more frequent screen changes. That’s built into the equipment spec from the start.

Large-Scale Production: 2-10 t/h

At 2-10 t/h, you’re looking at industrial-scale forage processing. These lines supply large feed mills, major export contracts, or regional distribution networks. The equipment is heavy-duty, built for continuous operation.

A grass pellet plant equipment in Canada package in the 2-10 t/h range runs $190,000 to $400,000 USD. At 5 t/h and above, you’re typically running multiple pellet mills—often two CZLH768 units—with a bale breaking system that can handle high volumes.

We installed a 6 t/h line for a producer in Manitoba that processes a mix of alfalfa, timothy, and brome grass into dairy feed pellets. Their line includes a receiving pit for truckloads of baled hay, a shredder to break the bales, hammer mills with 3mm screens, a rotary dryer, two CZLH768 mills running in parallel, coolers, and a bagging system with automatic palletizing. Investment was around $350,000. They run 16 hours a day during their peak season.

For straw pellet plant equipment in Canada at this scale, the drying system is often simpler because straw is typically drier at harvest. But the dust collection needs to be more robust—straw creates more fines than hay. We’ve done a 5 t/h straw line for a producer in Alberta that processes wheat and canola straw for bedding pellets. Their investment was on the lower end of this range because they skipped the dryer.

Industrial Scale: 3-12 t/h and Above

At 3-12 t/h and beyond, you’re talking about major industrial facilities. These are the kinds of operations that supply large feed manufacturers, export containers by the dozens, and run continuous shifts.

A 3-12 t/h straw pellet production line in Canada runs $220,000 to $450,000 USD. At 8 t/h and above, you’re looking at multiple CZLH768 mills, large-scale bale breaking systems, and fully automated controls with recipe management.

For 4-20 t/h lines, the range expands to $300,000 to $620,000 USD. We’ve installed a 10 t/h alfalfa line for a producer in Saskatchewan that exports to Japan. Their line includes three CZLH768 mills, a bale shredder that can process 50 round bales per hour, a multi-zone belt dryer, and a bagging system with stretch wrapping. The investment was over $500,000, but their annual output is pushing 20,000 tons.

For capacities beyond 20 t/h, we custom-engineer each line. At that scale, every project is different—the raw material supply chain, site layout, target markets, and automation preferences all drive the final configuration.

What Raw Materials Are We Talking About?

When Canadian customers ask about a hay pellet production line in Canada, they’re usually processing one of these:

• Alfalfa: The most common forage for pellets. High protein, good for dairy and equine markets. Can be baled as round or square bales. First-cutting is stemmier and harder to pellet; third-cutting is leafier and processes easier.
• Timothy: Popular for horse feed. Lower protein than alfalfa, but horse owners prefer it. Usually comes in square bales. Pellets tend to be softer and require less die wear.
• Mixed grass hay: Common for beef cattle and general livestock. Varies widely in composition. Can be challenging because the mix changes from field to field.
• Clover (red, white, alsike): Grown in some regions, often mixed with grass. Pellets well but can be dusty.
• Wheat straw: Used for bedding pellets and low-quality feed. Very fibrous, requires more grinding power. Usually comes off the field at lower moisture.
• Canola straw: Also used for bedding. Higher silica content, so dies wear faster. Popular in Alberta and Saskatchewan.
• Oat straw: Softer than wheat or canola straw. Easier to grind and pellet. Common in Eastern Canada.

The raw material form matters too. Round bales require a different bale breaker than square bales. Loose hay or chopped material can feed directly into the hammer mill. We’ve set up lines for all three configurations.

What’s Included in These Ranges?

When we quote a straw pellet production line in Canada, the package typically includes:

• Bale breaker or shredder (sized for round or square bales)
• Hammer mill with screens for your target particle size
• Batching system if mixing multiple forage types
• Conditioner for steam or moisture addition
• Pellet mill (CZLH series, one or multiple units)
• Cooler (counterflow or belt, depending on throughput)
• Screener for fines removal
• Bagging or bulk loading system
• Control panel with PLC
• Dust collection (essential for forage processing)

These are FOB Qingdao ranges. Shipping to Canadian ports, installation, and commissioning are additional. Some customers handle installation themselves; others want our team on-site for startup.

What Affects the Price?

If you’re comparing alfalfa pellet production line in Canada prices, here’s what creates the ranges:

• Raw material type: Alfalfa requires more die wear consideration than timothy. Straw requires more grinding power than hay.
• Bale type: Round bale systems are different from square bale systems. Some customers want the ability to handle both, which adds cost.
• Drying requirements: Fresh-cut hay can be 15-20% moisture and needs drying. Field-dried hay or straw may be ready to pellet with no dryer. That’s a $30,000-$80,000 difference.
• Automation level: A manual line with push-button controls costs less than a fully automated system with recipe management and remote monitoring.
• Pellet size: 6mm pellets for horses require different die specs than 8mm pellets for cattle. Fine-tuning the die for your specific market adds some cost.

A Note on What These Prices Represent

The numbers above are based on actual forage lines we’ve installed across Canada. But every grass pellet plant equipment in Canada project is different. Your bale type, hay species, moisture content at harvest, and target market all affect the final investment.

Also, what’s listed above is our main line configurations, but not everything we offer. We’ve built custom straw pellet production line in Canada systems for everything from certified organic alfalfa pellets to specialty blends for racehorses to bedding pellets for the equine market. If your forage operation has specific requirements, we’ve probably built something similar before.

If you’re running a feed mill, a pellet plant, or any operation that needs to reduce material size, the hammer mill is where it all starts. In Canada, these machines get used for everything from grinding corn and barley for livestock feed to processing wood chips for pellet production. The SFSP series we supply handles both—but the throughput looks very different depending on what you’re putting through it. Based on installations from Ontario to Alberta, here’s what you can expect to invest.

SFSP56*40 – Entry-Level Hammer Mill

This is the smallest in the line, with a 560mm rotor diameter and 400mm crushing chamber width. Rotor speed is 2980 rpm, hammer tip speed hits 88 m/s. Powered by a 37kW motor.

For grain applications, this is a solid grain hammer mill in Canada for smaller operations. Throughput on corn, wheat, or barley runs 3-5 t/h depending on screen size. We’ve installed this for a few poultry farms in Ontario that wanted to grind their own corn. They run a 4mm screen for mash feed and the machine keeps up with their mixing line.

For wood applications, the same machine handles 0.5-0.6 t/h of wood chips or sawdust. A small sawmill in British Columbia uses one to grind their planer shavings before pelleting. The throughput is lower, but for a starter operation, it’s enough to prove the concept.

Price range: $12,000 to $18,000 USD. The spread depends on screen configuration and whether you need magnetic separation built into the feed.

SFSP66*60 – Mid-Size Grinder

Stepping up to the 660mm rotor diameter models. The SFSP66*60 has a 600mm crushing chamber width and runs at 2980 rpm. Hammer tip speed increases to 103 m/s. Power options: 55kW or 75kW.

As a feed hammer mill in Canada, this size is popular for mid-size feed mills. Grain throughput with the 55kW motor is 5-6 t/h. Upgrade to 75kW and you can push 6-7 t/h. A dairy operation in Quebec uses this model with a 55kW motor to grind corn and barley for their TMR rations. They run about 1,500 tons through it annually.

For wood applications, the same machine does 1.0-1.2 t/h with the 55kW motor. A pellet producer in Alberta uses this to grind clean sawdust before pelleting. They found that upgrading to the 75kW motor helped maintain throughput when processing wetter material.

Price range: $16,000 to $26,000 USD. The higher end includes heavier-duty hammers and screens for abrasive materials like corn with high silica content.

SFSP66*80 – Commercial Scale

This model has an 800mm crushing chamber width. Motor options: 75kW, 90kW, or 110kW.

For grain, this is where you get serious commercial capacity. With the 75kW motor, throughput hits 8-10 t/h on corn and wheat. With the 90kW motor, you’re looking at 10-12 t/h. A grain grinding mill in Canada at this scale is what you’d find in a regional feed mill serving multiple farms. We installed one for a cooperative in Saskatchewan that processes about 8,000 tons of grain annually.

For wood, the SFSP66*80 handles 2.0-2.5 t/h of wood chips or sawdust with the 90kW motor. This is a common size for wood hammer mill in Canada installations in mid-size pellet plants. A producer in New Brunswick runs one of these with a 90kW motor, processing mixed softwood chips at about 2.2 t/h. They run it about 1,500 hours a year.

Price range: $20,000 to $36,000 USD. The range reflects motor size and whether you need a heavier rotor for continuous operation.

SFSP66*100 – High-Volume Processing

Chamber width expands to 1000mm on this model. Motor options: 110kW, 132kW, or 160kW.

Grain throughput ranges from 15-17 t/h with the 110kW motor, up to 20-22 t/h with the 160kW motor. This is industrial wood hammer mill in Canada territory for large feed mills. A hog operation in Manitoba uses one with a 132kW motor to grind about 15,000 tons of barley annually for their finishing rations.

For wood, the SFSP66*100 handles 3.0-4.0 t/h with the 132kW motor. A biomass hammer mill in Canada at this scale is what you’d find in a commercial pellet plant. A facility in British Columbia uses one to process sawmill residuals before their 4 t/h pellet line. They run it about 12 hours a day, five days a week.

Price range: $30,000 to $50,000 USD. The higher end includes automated screen change systems and heavier-duty bearing assemblies.

SFSP66*120 – Large-Scale Production

Chamber width at 1200mm. Motor options: 160kW, 185kW, or 220kW.

Grain throughput: 25-27 t/h with the 160kW motor, 30-32 t/h with the 185kW motor. This is the kind of animal feed hammer mill in Canada you’d see in a major commercial feed mill supplying hundreds of farms. A feed manufacturer in Quebec runs one with a 185kW motor, processing about 25,000 tons of corn and wheat annually.

For wood, throughput runs 4.0-5.0 t/h with the 160kW motor, up to 5.0-6.0 t/h with the 185kW motor. A wood chip crusher in Canada at this scale is what you’d find in a large pellet plant. A producer in Alberta uses one to process beetle-kill pine chips before their 6 t/h pellet line.

Price range: $45,000 to $68,000 USD. The spread reflects motor selection and whether you need special metallurgy for abrasive materials.

SFSP66*150 – Heavy-Duty Industrial

The largest in the line. 1500mm crushing chamber width. Motor options: 220kW and up.

Grain throughput hits 40-50 t/h. This is for major industrial feed mills, the kind that supply multiple provinces or export markets. We’ve installed these for large feed manufacturers in Ontario and Alberta.

For wood, throughput reaches 7.0-8.0 t/h. A wood waste grinder in Canada at this scale is what you’d find in a major pellet export facility. A producer in British Columbia runs one of these with a 220kW motor, processing about 30,000 tons of wood chips annually for their export pellet line.

Price range: $70,000 to $95,000 USD. The high end includes fully automated screen changes, vibration monitoring, and heavy-duty rotor balancing.

What These Prices Include

When we quote a biomass grinder in Canada, the price is for the complete SFSP hammer mill unit: rotor assembly, hammers, screens (one set of your specified size), motor, and control starter. These are FOB Qingdao ranges. Shipping to Canadian ports, customs clearance, and installation are additional.

The SFSP series is what we call the drop-shaped hammer mill. The design improves airflow through the grinding chamber, which matters when you’re processing fluffy material like sawdust or when you’re trying to hit fine grinds for feed applications. The shape reduces dead spots where material can accumulate.

What Affects the Price?

If you’re comparing wood hammer mill in Canada prices or feed hammer mill in Canada prices, here’s what creates the ranges beyond just the model size:

• Screen size: Finer screens (0.5-2mm) require more horsepower to push material through. If you’re grinding for fish feed or fine mash, you’ll need a larger motor than if you’re just breaking material down to 6-8mm for pelleting.
• Material type: Corn grinds differently than barley. Wood species vary in density and fiber structure. Hardwoods like maple require more power than softwoods like pine. Abrasive materials like corn with high silica or bark with grit will wear hammers faster and may require upgraded metallurgy.
• Feed system: If you’re feeding material directly from a conveyor or auger, that’s different from feeding with a magnet separator or metering bin. Some customers handle this separately; others want us to supply an integrated feed solution.
• Automation: Basic models have manual controls. Automated systems with variable-speed feeders and motor load monitoring cost more but can improve efficiency and protect the machine from overload.

A Note on What These Machines Do

The SFSP series is designed to take material up to 5cm in size. For grain, that means whole corn or barley kernels. For wood, that means chips or sawdust that have already been through a chipper or shredder. The hammer mill reduces everything to whatever particle size you need for your next step—whether that’s 6mm for pellet production or 1mm for mash feed. Swap the screen, change the particle size. That’s the flexibility these mills offer.

For anyone building a biomass grinder in Canada operation, the hammer mill is often the bottleneck if it’s undersized. We see this a lot—someone specs a pellet mill that can do 4 t/h, then realizes their hammer mill can only feed it at 2 t/h. The SFSP line gives you room to match your downstream equipment.

If you’re running a sawmill, a forestry operation, or a biomass pellet plant, the chipper is often the first piece of equipment in your line. In Canada, that means processing everything from clean sawmill slabs to logging slash with bark and branches mixed in. The XPJ series drum chippers we supply handle the range. Based on installations across BC, Alberta, Quebec, and Ontario, here’s what to expect.

XPJ500x230 – Entry-Level Drum Chipper

This is the smallest in the line, with an infeed opening of 500mm x 230mm. It handles material up to 230mm in diameter—think small logs, branches, or sawmill slabwood. Feed system uses two motors (4kW + 3kW) to pull material in. Main motor is 75kW.

This size works well for a small sawmill that wants to chip their slabwood and edgings instead of landfilling it. A mill in Ontario uses one of these to process about 2-3 tons per hour of mixed softwood slabs. The chips go to a local pellet plant. For anyone looking at a rotary drum chipper for sale Canada at the entry level, this is where you start.

Price range: $16,000 to $22,000 USD. The spread depends on whether you need the discharge conveyor and hydraulic system included.

XPJ680x300 – Small Commercial Chipper

Infeed opening expands to 680mm x 300mm, handling material up to 300mm in diameter. Same feed motor configuration (4kW + 3kW), main motor bumped to 90kW.

This is a common size for mid-size sawmills and forestry operations. A facility in British Columbia uses one to chip logging residues—tops and branches that used to be burned in slash piles. The chipper runs about 1,000 hours a year, producing chips for a local pellet plant. As a wood chipper for biomass in Canada, this size is popular for operations feeding 2-3 t/h of chips to a pellet line.

Price range: $20,000 to $28,000 USD. The range reflects whether you want the hydraulic system for adjusting feed rolls.

XPJ500x500 – Compact High-Capacity

This model has a 500mm x 500mm infeed opening, handling material up to 500mm in diameter—bigger logs and larger slabwood. Feed motors: 4kW + 3kW. Main motor: 110kW. Six fly knives (compared to two on the smaller models).

The larger infeed opening means you can feed bigger material without pre-cutting. A sawmill in Alberta uses this model to process whole slabs and edgings up to 18 inches wide. They’re running about 4-5 tons per hour. For a drum chipper for sawmill waste in Canada, this size hits a sweet spot for medium-sized mills.

Price range: $24,000 to $34,000 USD. The higher end includes heavier-duty knives and a reinforced infeed system for handling larger material.

XPJ850x500 – Commercial Scale

Infeed opening: 850mm x 500mm, handling material up to 500mm in diameter. Feed motors: 4kW + 3kW. Main motor: 132kW. Ten fly knives, three stationary knives.

This is where you get into serious commercial capacity. A forestry operation in northern BC uses one of these to chip logging slash—full trees after limbs are removed. They’re processing about 8-10 tons per hour, feeding a biomass shredder for forestry residue in Canada operation that supplies a pellet plant. The ten-knife setup gives you cleaner chips with less fines than the smaller models.

Price range: $32,000 to $45,000 USD. The range reflects motor selection and whether you need a heavier rotor assembly for continuous operation.

XPJ1200x500 – Large-Scale Production

Infeed opening: 1200mm x 500mm, handling material up to 500mm in diameter. Feed motors upgraded to 5.5kW + 4kW. Main motor: 200kW. Fourteen fly knives, three stationary knives.

This is what you’d find in a major sawmill or forestry operation. A facility in Quebec uses one to process whole logs that aren’t suitable for lumber—crooked trees, small-diameter logs, and slabs from their mill. They’re running about 15-18 tons per hour, supplying chips to a pellet plant and a pulp mill. As a wood waste grinder in Canada at this scale, it runs 12-14 hours a day during the processing season.

Price range: $48,000 to $68,000 USD. The higher end includes the hydraulic pump system (3kW) and a fully enclosed infeed section for safety.

XPJ850x600 – Heavy-Duty Industrial

Infeed opening: 850mm x 600mm, handling material up to 600mm in diameter. Feed motors: 7.5kW + 7.5kW—the most powerful feed system in the line. Main motor: 200kW. Fourteen fly knives, three stationary knives.

This model is built for the toughest applications. A forestry operation in British Columbia uses one to chip whole trees—including those with some dirt and bark. The larger infeed height (600mm) lets them feed material that’s been felled and skidded without a lot of pre-sorting. They’re processing about 20 tons per hour during peak season. This is the kind of wood chipper for biomass in Canada that supplies large pellet plants and industrial boilers.

Price range: $58,000 to $85,000 USD. The spread reflects motor options and whether you need a discharge conveyor and magnetic separator for metal removal.

What These Prices Include

When we quote a rotary drum chipper for sale Canada, the price includes the chipper unit with standard knives, the feed roll system, main motor, and basic controls. These are FOB Qingdao ranges. Shipping to Canadian ports, customs clearance, and installation are additional.

The XPJ series is a drum-type chipper—the drum rotates with knives mounted on it, and material is fed against a stationary bed knife. This design gives you consistent chip size with relatively low fines, which matters for pellet production. The chips come out in the 20-40mm range, ready for the hammer mill or directly for some applications.

What Affects the Price?

If you’re comparing drum chipper for sawmill waste in Canada prices, here’s what creates the ranges:

• Infeed size: Larger infeed openings cost more but let you feed bigger material without pre-cutting. That can save labor costs on the front end.
• Knife count: More knives give you better chip quality and more consistent sizing. The XPJ500x500 and larger models have 6-14 knives versus 2 knives on the entry models.
• Feed system: Hydraulic feed rolls with variable speed control cost more than fixed-speed mechanical feeds. But they handle irregular material better and reduce jamming.
• Discharge configuration: Some customers want a discharge conveyor to load trucks or feed directly into a bin. Others discharge onto a pile. That’s a $3,000-$8,000 difference depending on length and type.
• Portability: Some operations want a chipper on a trailer or skid for moving between sites. That adds cost for the chassis and wheels.

A Note on What These Machines Do

The XPJ drum chipper takes logs, branches, slabwood, and edgings and turns them into uniform chips in the 20-40mm range. That’s the ideal size for further processing in a hammer mill or for direct sale to pulp mills and pellet plants. The screen size can be customized if you need a different chip size, though the 20-40mm range works for most applications.

For anyone building a biomass shredder for forestry residue in Canada operation, the chipper is often the first bottleneck. Undersize the chipper and you’re hand-sorting material. Size it right and you can feed whole trees, slabs, and logging slash without pre-processing.

If you’re running a feed mill or a livestock operation, the mixer is where ingredients become a consistent ration. In Canada, that means handling everything from straight grain rations for cattle to complex poultry formulas with micro-ingredients, and sometimes sticky additions like molasses. The SLHJ, SLHSJ, SLHY, STHJ, and ZGH series cover the range. Based on installations across the country, here’s what to expect.

SLHJ Series – Single-Shaft Paddle Mixers

This series uses a single shaft with paddles arranged to create a fluidized mixing action. It’s designed for feed, chemical, organic fertilizer, and even sticky materials. The mixing action is vigorous and fast—typically 2-3 minutes per batch.

The SLHJ1A and SLHJ1B (500kg batch) run on 11kW motors. Carbon steel (SLHJ1A) is for standard feed applications. Stainless steel (SLHJ1B) is for corrosive materials or operations that need to meet higher sanitation standards. A poultry farm in Ontario uses the carbon steel version for their layer rations. A specialty feed manufacturer in Quebec uses the stainless version for organic formulas.

The SLHJ2A and SLHJ2B (1000kg batch) use 22kW motors. This is a popular size for mid-size feed mills. A dairy operation in Alberta runs one of these—about 8-10 batches per day, mixing their corn, barley, and mineral blends.

The SLHJ3A (1500kg batch, 30kW), SLHJ4A (2000kg batch, 37kW), and SLHJ6A (3000kg batch, 55kW) are for commercial-scale operations. A feed mixing system in Canada at this scale is what you’d find in a regional feed mill serving multiple farms.

Price range: $8,000 to $28,000 USD. The smaller 500kg units start around $8,000-$12,000. The 1000kg carbon steel version runs $12,000-$16,000, with stainless adding $2,000-$3,000. The larger commercial units—1500kg to 3000kg—range from $18,000 to $28,000 depending on configuration and material.

SLHSJ Series – Twin-Shaft Paddle Mixers

Twin-shaft mixers have two counter-rotating shafts with paddles. This design gives you even faster mixing times—typically 30-60 seconds per batch—and better handling of materials with different particle sizes. It’s widely used in feed, food, chemical, and pharmaceutical applications.

The SLHSJ0.5A and SLHSJ0.5B (250kg batch) run on 5.5kW motors with chain drive. These are compact units for smaller operations or pre-mix lines. A custom feed blender in British Columbia uses the stainless version for small-batch specialty formulas.

The SLHSJ1.0A and SLHSJ1.0B (500kg batch) use 7.5kW motors. This size works well for mid-size feed mills or as a pre-mixer for micro-ingredients. A hog operation in Manitoba uses one to mix their mineral premixes before adding to the main mixer.

The SLHSJ2.0A (1000kg batch) runs on 18.5kW, and the SLHSJ4.0A (2000kg batch) uses 30kW. These are commercial-scale units. A horizontal feed mixer in Canada at this capacity is what you’d find in larger feed plants. A poultry feed manufacturer in Ontario runs the 2000kg model, mixing about 40 batches per day.

Price range: $6,000 to $24,000 USD. The 250kg units start around $6,000-$9,000. The 500kg carbon steel version runs $8,000-$12,000, with stainless adding $2,000-$3,000. The 1000kg and 2000kg commercial units range from $12,000 to $24,000.

SLHY Series – Single-Shaft Ribbon Mixers

This is the classic ribbon mixer design—a single shaft with inner and outer ribbons that move material in opposite directions. It’s widely used in feed mills for mixing dry powders and granular materials. The mixing action is gentler than paddle mixers, which matters for fragile ingredients.

The SLHY0.5A (250kg batch, 4kW) is a manual-discharge unit—good for small farms or starter operations. A mixed farm in New Brunswick uses one to blend their own grain rations for a few hundred head of cattle.

The SLHY1.0A (500kg batch, 7.5kW) comes in manual-discharge and pneumatic-discharge versions. The pneumatic version (SLHY1.0A with air gate) is more common in commercial operations. A feed mill in Quebec uses the pneumatic version for their custom blends.

The SLHY2.5L (1000kg batch, 18.5kW), SLHY3.5L (1500kg batch, 30kW), SLHY5.0L (2000kg batch, 37kW), and SLHY7.5L (3000kg batch, 45kW) are for commercial feed mills. A livestock feed mixer in Canada at this scale is what you’d find in a regional feed plant. One in Alberta runs the 2000kg model for their cattle finishing rations.

Price range: $2,800 to $20,000 USD. The 250kg manual-discharge unit starts around $2,800-$4,000. The 500kg manual version runs $4,000-$6,000; pneumatic adds $1,000-$1,500. The 1000kg commercial units run $8,000-$12,000, with larger 1500kg-3000kg units ranging from $12,000 to $20,000.

STHJ Series – High-Speed Molasses Mixers

This is a specialized unit for adding molasses to cattle and other ruminant feeds. Molasses is sticky and hard to mix uniformly with standard mixers. The STHJ series is a continuous, high-speed mixer that sits upstream of the pellet mill. It’s designed to handle up to 30 t/h.

The STHJ35x200 (15-20 t/h) runs on 30kW. The STHJ40x250 (20-25 t/h) uses 37kW. The STHJ50x275 (25-30 t/h) runs on 45kW. These are almost always carbon steel (A series), though stainless (B series) is available for corrosive liquid additions.

A feed batching mixer in Canada for molasses is common in cattle feed operations across Alberta and Ontario. One feedlot in Alberta uses the 25-30 t/h model to add molasses to their finishing rations before pelleting. The mixer runs about 10 hours a day during peak season.

Price range: $18,000 to $32,000 USD. The 15-20 t/h model runs $18,000-$24,000. The 20-25 t/h model is $22,000-$28,000. The 25-30 t/h unit runs $26,000-$32,000. Stainless steel construction adds about 15-20% to the base price.

ZGH Series – Rotary Drum Mixers

This is a simple, low-cost option for small-batch mixing. The drum rotates, tumbling the material to achieve uniform distribution. It’s commonly used for pre-mixes, additives, and small-batch specialty formulas where a large mixer isn’t justified.

The ZGH-100 (100kg batch) runs on 2.2kW. The ZGH-200 (200kg batch) also uses 2.2kW. The ZGH-300 (300kg batch) uses 3kW. The ZGH-500 (500kg batch) uses a 3kW motor plus a 4kW drive for the drum rotation.

A animal feed mixer in Canada at this scale is what you’d find in a small farm operation or a custom feed blender doing small runs. A horse feed operation in Ontario uses the 300kg model for their vitamin and mineral pre-mixes. They run about 5-6 batches a week.

Price range: $3,500 to $8,500 USD. The 100kg unit runs $3,500-$4,500. The 200kg unit is $4,000-$5,500. The 300kg model runs $5,000-$7,000. The 500kg unit is $6,500-$8,500.

What These Prices Include

When we quote a feed mixer in Canada, the price includes the mixer unit with standard ribbons or paddles, the motor, drive system, and discharge mechanism (manual or pneumatic depending on the model). These are FOB Qingdao ranges. Shipping to Canadian ports, installation, and commissioning are additional.

What Affects the Price?

If you’re comparing paddle feed mixer in Canada prices versus ribbon feed mixer in Canada prices, here’s what creates the differences:

• Material of construction: Carbon steel is standard. Stainless steel (usually 304) adds 15-25% to the price but is necessary for corrosive materials, organic certification, or high-moisture applications.
• Discharge type: Pneumatic (air-operated) gates cost more than manual gates but are standard for automated batching systems. Add $1,000-$2,000 depending on size.
• Drive configuration: Direct drive (SLHJ series) costs less than chain drive (SLHSJ series). But chain drive gives you more flexibility in placement since the motor can be offset.
• Special features: Liquid addition systems, heating jackets, or custom inlet configurations add to the base price. We’ve done mixers with steam injection ports, which required custom engineering.
• Batch size: Larger batch sizes cost more, but the cost per kg goes down. A 250kg mixer might be $4,000; a 3000kg mixer might be $20,000—about 30% less per kg of capacity.

Which Mixer for Which Application?

ZGH drum mixers: Low-cost option for small batches, pre-mixes, and specialty formulas. Good for starter operations.

SLHJ paddle mixers: Best for fast mixing, sticky materials, and applications where you need a short cycle time. Good for feed mills running high volumes.

SLHSJ twin-shaft mixers: Even faster mixing, better for formulas with widely varying particle sizes. Common in commercial feed plants.

SLHY ribbon mixers: Gentler mixing, good for fragile ingredients. Popular in smaller feed mills and farm operations.

STHJ molasses mixers: The go-to for adding liquids to cattle feed. Continuous operation, high capacity.

If you’re making wood pellets, drying is usually the biggest bottleneck and often the largest investment after the pellet mill itself. In Canada, that means taking wet sawmill residuals from 40-50% moisture down to 10-12% before pelleting. The same dryers also handle grass, straw, and other biomass. The rotary drum dryers we supply cover the range. Based on installations across the country, here’s what to expect.

Small-Scale Dryers: φ0.6×6 and φ0.8×8

These are the entry-level sizes. The φ0.6×6 has a 0.6m diameter and 6m length. The φ0.8×8 is 0.8m diameter and 8m length. Both are single-pass dryers—material travels through the drum once before exiting.

These sizes work for small operations. A sawmill in Ontario uses the φ0.8×8 to dry about 0.5-0.8 t/h of sawdust from their planer. They’re running inlet temperature around 400°C, outlet around 75°C. It’s enough to feed their 0.5 t/h pellet line.

For wood chip rotary dryer in Canada applications at this scale, you’re looking at throughputs of 0.5-1.5 t/h depending on incoming moisture. If your material is wetter than 40%, throughput drops. If it’s already at 30%, you can push higher.

Price range: $15,000 to $28,000 USD. The φ0.6×6 starts around $15,000-$20,000. The φ0.8×8 runs $20,000-$28,000, depending on whether you need the burner and cyclone included.

Mid-Size Dryers: φ1.2×12 and φ1.5×15

The φ1.2×12 has a 1.2m diameter and 12m length. The φ1.5×15 is 1.5m diameter and 15m length. These are single-pass units that start to get serious about capacity.

A sawdust rotary dryer in Canada at this scale is common for mid-size pellet plants. A facility in British Columbia uses the φ1.5×15 to dry about 2-2.5 t/h of mixed softwood sawdust. Incoming moisture around 45%, outlet at 12%. They run inlet temperature at 450°C, outlet at 80°C. It feeds their MZLH678 pellet mill.

For biomass rotary dryer in Canada applications, these sizes handle 1.5-3.5 t/h depending on material and moisture. Wood chips dry slower than sawdust because of the larger particle size. Sawdust dries faster but has more fines that can be carried out in the exhaust.

Price range: $28,000 to $45,000 USD. The φ1.2×12 runs $28,000-$36,000. The φ1.5×15 runs $35,000-$45,000. The range reflects whether you want a complete system with burner, cyclone, and exhaust fan, or just the drum.

Commercial Dryers: φ1.8×18 and φ1.8×20

These are 1.8m diameter units with 18m or 20m length. Single-pass design. At this scale, you’re into commercial production.

A straw rotary dryer in Canada at this size is what you’d find at a forage pellet plant. A facility in Saskatchewan uses the φ1.8×18 to dry alfalfa from 18% moisture down to 12%. Throughput is about 3-4 t/h. For wood applications, a pellet plant in Quebec uses the φ1.8×20 to dry sawmill chips at about 4-5 t/h.

For grass rotary dryer in Canada applications, these sizes handle 3-5 t/h depending on material. Grass and alfalfa dry faster than wood because they’re less dense, but they also produce more dust, so the cyclone and dust collection need to be properly sized.

Price range: $45,000 to $68,000 USD. The φ1.8×18 runs $45,000-$58,000. The φ1.8×20 runs $52,000-$68,000. The spread includes whether you need a heavier-duty flight design for abrasive materials like alfalfa or wood with high bark content.

Large Single-Pass: φ1.8×36

This is a 1.8m diameter unit with 36m length—double the length of the previous models. The extra length gives you more residence time, which is critical for materials that dry slowly or for applications where you need very precise final moisture.

A wood chip rotary dryer in Canada at this scale is what you’d find in a major pellet plant. A facility in British Columbia uses one to dry mixed softwood chips at about 6-8 t/h. Incoming moisture around 50%, outlet at 12%. The long drum gives them the residence time they need without having to run inlet temperatures too high.

For alfalfa rotary dryer in Canada applications, this size handles 5-7 t/h. A forage processor in Alberta uses the φ1.8×36 to dry alfalfa before pelleting for export. They run it about 16 hours a day during their processing window.

Price range: $68,000 to $95,000 USD. The length and the heavy-duty construction for continuous operation put this at the higher end of the single-pass range.

Triple-Pass Dryers: φ1.8x12x3C and φ1.8x24x3C

These are three-pass dryers. The material travels through three concentric drums, which gives you much longer effective drying time in a shorter footprint. The φ1.8x12x3C has a 1.8m diameter outer drum, 12m length, with three passes. The φ1.8x24x3C has 24m length with three passes—the effective drying length is about 3x the physical length.

Triple-pass dryers are more efficient for certain materials and space-constrained sites. A pellet plant in Ontario uses the φ1.8x12x3C to dry sawdust at about 4 t/h. The shorter footprint let them fit the dryer into an existing building.

For industrial rotary dryer in Canada applications, triple-pass designs are popular when space is limited or when you’re drying materials that are prone to scorching. The gentler material handling reduces fines generation compared to single-pass units.

Price range: $55,000 to $180,000 USD. The φ1.8x12x3C runs $55,000-$85,000. The φ1.8x24x3C runs $95,000-$180,000. The wide range reflects the burner system, automation level, and whether you need a multi-cyclone for dust control.

What These Prices Include

When we quote a rotary drum dryer in Canada, the base price includes the drum with flights, trunnion rollers, drive system, and seals. Burner, cyclone, exhaust fan, and control panel are typically additional—add $10,000-$40,000 depending on size and whether you need gas, oil, or biomass burner.

These are FOB Qingdao ranges. Shipping to Canadian ports, installation, and commissioning are additional. The large dryers (φ1.8×36 and triple-pass units) often ship in sections and require on-site assembly.

What Affects the Price?

If you’re comparing sawdust rotary dryer in Canada prices, here’s what creates the ranges:

• Material type: Sawdust dries faster than wood chips because of the higher surface area. Grass and alfalfa dry faster than wood but create more dust. The flight design inside the drum changes based on material—some materials need lifting flights, others need cascade flights.
• Moisture content: If you’re starting at 50% moisture and need to get to 10%, you need more residence time than if you’re starting at 30%. That means a longer drum or a triple-pass design.
• Burner type: Natural gas burners are common in urban areas. Propane or oil burners are used where gas isn’t available. Biomass burners (using wood waste) cost more upfront but can have lower operating costs if you have free fuel. Add $10,000-$30,000 depending on type and size.
• Dust collection: Wet scrubbers cost more than cyclones but are sometimes required by local regulations. A multi-cyclone might add $5,000-$15,000; a wet scrubber can add $20,000-$40,000.
• Automation: Basic dryers have manual temperature controls. Automated systems with PLC, moisture sensors, and variable-speed drives cost more but can save fuel and improve consistency.

Which Dryer for Which Application?

Triple-pass models: Space-constrained sites, materials that need gentle handling. Efficient footprint but higher cost per ton of capacity.

φ0.6×6 and φ0.8×8: Small sawmills, farm-scale operations. 0.5-1.5 t/h throughput. Good for testing the market before scaling up.

φ1.2×12 and φ1.5×15: Mid-size pellet plants, forage operations. 1.5-3.5 t/h. Most common for operations feeding a single MZLH420 or MZLH520 mill.

φ1.8×18 and φ1.8×20: Commercial pellet plants. 3-5 t/h. Often paired with MZLH678 or MZLH768 mills.

φ1.8×36: Large commercial operations. 6-8 t/h. For plants running multiple pellet mills.

If you’re drying something that can’t be tumbled—like extruded fish feed, pet food kibble, or delicate fruits and vegetables—a belt dryer is usually the right answer. Unlike rotary dryers that toss material around, belt dryers gently move product on perforated belts with warm air passing through. In Canada, we’ve installed these for aquaculture operations, pet food manufacturers, and specialty food processors. Here’s what to expect.

DHG Series – Electric-Heated Belt Dryers

These units use electric heating elements rather than steam or gas. They’re a good choice for smaller operations or facilities where running steam lines isn’t practical. The DHG series uses a 5-layer belt configuration with variable speed control.

DHG-400: This is the smallest in the line. 0.8m belt width, 13㎡ drying area. Total power is 40kW for heating plus 0.55kW×4 for the drive motors plus 0.55kW for the exhaust fan. A small fish feed operation in New Brunswick uses one of these to dry about 100-150 kg/h of extruded salmon feed. The gentle drying prevents the pellets from cracking—a problem they had with their previous batch dryer. For anyone looking at a fish feed dryer in Canada at starter scale, this is where you begin.

DHG-500: Belt width expands to 1.0m with 21㎡ drying area. Power: 50kW heating plus 2.2kW×2 drive motors plus 0.75kW exhaust. This size works for mid-size aquaculture operations. A trout hatchery in Ontario uses one to dry about 250-300 kg/h of feed. They run it about 8 hours a day during their peak production season.

DHG-1000: 1.2m belt width, 43㎡ drying area. Power: 70kW heating plus 2.2kW×3 drive motors plus 1.5kW exhaust. A pet food manufacturer in Quebec uses this model to dry their premium kibble line. The pet food dryer in Canada market is growing, and this size suits small to mid-size producers.

DHG-2000: 1.6m belt width, 58㎡ drying area. Power: 132kW heating plus 2.2kW×3 drive motors plus 1.5kW exhaust. This is the largest electric-heated model. A specialty food processor in British Columbia uses one to dry fruit slices—apples and pears—for the health food market. Gentle drying preserves color and flavor better than rotary drying.

Price range: $13,000 to $45,000 USD. The DHG-400 starts around $13,000-$18,000. The DHG-500 runs $18,000-$25,000. The DHG-1000 is $25,000-$35,000. The DHG-2000 runs $32,000-$45,000. The range reflects automation level and whether you need stainless steel construction for food-grade applications.

QHG Series – Steam-Heated Belt Dryers

For larger operations or facilities with existing steam boilers, steam-heated belt dryers are more economical to run. The heating cost is lower than electric, though the upfront investment is higher. These use the same belt configurations as the DHG series but with steam heat exchangers instead of electric elements.

QHG-500: 1.0m belt width, 21㎡ drying area. Drive motors: 2.2kW×2 plus 0.75kW exhaust. No electric heating element—instead, it uses steam coils. A vegetable processor in Ontario uses one to dry chopped carrots and onions for soup mixes. The vegetable dryer in Canada market has been steady, and steam heat gives them better cost control.

QHG-1000: 1.2m belt width, 43㎡ drying area. Drive motors: 2.2kW×3 plus 1.5kW exhaust. This is a common size for biomass belt dryer in Canada applications where the material needs gentle handling. A facility in Alberta uses one to dry alfalfa for horse feed pellets. The belt dryer prevents the leaf material from blowing away—a problem with rotary dryers.

QHG-2000: 1.6m belt width, 58㎡ drying area. Drive motors: 2.2kW×3 plus 1.5kW exhaust. This is the largest standard model. A sawdust belt dryer in Canada at this scale is less common—most sawdust goes through rotary dryers—but for applications where dust control is critical, belt dryers work. A wood pellet plant in British Columbia uses one for their premium line where they want minimal fines.

Price range: $25,000 to $85,000 USD. The QHG-500 runs $25,000-$38,000. The QHG-1000 is $38,000-$55,000. The QHG-2000 runs $50,000-$85,000. The spread reflects the heat exchanger configuration, stainless steel options, and whether you need multi-zone temperature control.

What These Prices Include

When we quote a belt dryer in Canada, the base price includes the dryer cabinet, belt system with drives, heating system (electric elements or steam coils), exhaust fans, and basic controls. These are FOB Qingdao ranges. Shipping to Canadian ports, installation, and commissioning are additional.

For steam-heated models, the steam supply system (boiler, piping, traps) is not included. For electric models, you’ll need to have adequate electrical service—the DHG-2000 pulls 132kW plus drives, so you’re looking at a substantial power requirement.

What Affects the Price?

If you’re comparing industrial belt dryer in Canada prices, here’s what creates the ranges:

• Heating type: Electric is simpler to install but costs more to operate. Steam has higher upfront cost but lower operating cost if you already have a boiler. Add $10,000-$20,000 for steam compared to electric for comparable sizes.
• Material of construction: Carbon steel is standard. For food-grade applications—pet food, fruits, vegetables—stainless steel is usually required. Add 20-40% for stainless.
• Belt material: Standard belts are stainless steel mesh. For sticky materials like fruit, you might need a non-stick coating or a different belt design. Add $2,000-$8,000 depending on the belt type.
• Zone control: Multi-zone dryers let you set different temperatures in different sections of the dryer. This is important for materials that need a specific drying profile—high heat early to drive off surface moisture, lower heat later to prevent case hardening. Add $5,000-$15,000 depending on the number of zones.
• Dehumidification system: All these units have exhaust fans to remove humid air. For applications where you need to recover heat or control exhaust emissions, you might add a heat recovery system or scrubber. Add $5,000-$20,000.

Canadian Applications for Belt Dryers

The belt dryers we’ve installed in Canada cover a surprising range of applications:

• Fish feed: Salmon hatcheries in BC, trout farms in Ontario, and shrimp operations in New Brunswick all use belt dryers. Extruded pellets come out of the extruder at 22-25% moisture and need to come down to 8-10% without cracking. Belt dryers do that consistently.
• Pet food: The pet food dryer in Canada market has grown as more manufacturers set up regional production. Kibble needs gentle drying to maintain uniform expansion and prevent scorching. A pet food plant in Ontario runs a QHG-2000 for their main line.
• Fruits and vegetables: A processor in British Columbia dries apples, pears, and berries for the health food market. Low-temperature drying preserves color, flavor, and nutritional content. Electric heat gives them precise control.
• Alfalfa and forages: For premium horse feed, some producers use belt dryers to prevent leaf loss. Rotary dryers can blow the leaf material out the exhaust; belt dryers keep it in the product. A forage operation in Alberta uses a QHG-1000 for their export-grade alfalfa pellets.
• Specialty biomass: For materials that are dusty or have fine particles, belt dryers are often a better choice than rotary. A biomass belt dryer in Canada for wood fines or bark dust keeps material contained and reduces emissions.

Belt Dryer vs. Rotary Dryer

This is a question we get a lot. If you’re drying something that can handle tumbling—sawdust, wood chips, grain—a rotary dryer is usually cheaper per ton of capacity. But if you’re drying something delicate, something that needs to maintain shape, or something that would create excessive dust in a rotary dryer, a belt dryer is the right choice.

The trade-off is cost. For the same throughput, a belt dryer typically costs 30-50% more than a rotary dryer. But for fish feed, pet food, and food products, there’s really no alternative.

A Note on Customization

The models above are our standard sizes. But we’ve built custom belt dryers for Canadian operations with specific requirements—extra-long drying zones for high-moisture materials, stainless steel construction for food-grade applications, and multi-pass configurations for facilities with limited floor space. If your application doesn’t fit the standard sizes, we can design something that does.

If you’re selling pellets or feed in bags, manual bagging gets old fast. It’s slow, inconsistent, and labor-intensive. The DCS series automatic packing machines we supply handle everything from wood pellets to feed to powders. Based on installations across Canada—from small farms to large commercial pellet plants—here’s what to expect.

DCS-50W – Gravity Feed for Granules

This is the basic model for free-flowing granular materials. Uses gravity feed—material flows from a hopper directly into the bag. The scale weighs and cuts off when it hits the target weight. It’s simple, reliable, and easy to maintain.

The DCS-50W runs at 2-3 bags per minute. Power: 0.55kW for the scale plus 0.37kW for the bag clamp and discharge. It handles pellets, grains, and other free-flowing materials.

A small wood pellet producer in Ontario uses one of these. They’re bagging about 1.5 tons per hour into 40lb bags for local farm stores. The gravity feed is simple enough that one operator runs the bagging line while also handling the forklift.

For anyone looking at a wood pellet packing machine in Canada at the entry level, this is where you start.

Price range: $5,000 to $8,500 USD. The lower end is a basic machine with manual bag placement; the higher end includes a bag holder and a simple conveyor.

DCS-50K – High-Speed Gravity Feed

Same gravity feed principle as the 50W, but with a faster scale and bag handling system. This model runs at 5-6 bags per minute—about double the speed of the 50W. Power: 0.55kW plus 0.37kW.

A pellet bagging machine in Canada at this speed is common for mid-size operations. A bedding pellet producer in Alberta uses one to bag about 3 tons per hour into 40lb bags. They run it about 6 hours a day, and one operator handles both the bagging and palletizing.

The faster cycle time comes from a more responsive scale and a bag clamp that positions the bag more quickly. If you’re running a shift and need to get through 15-20 tons, this is the minimum speed you want.

Price range: $6,500 to $10,000 USD. The spread depends on whether you need a sewing head integrated into the line or if you’re using pre-sewn bags.

DCS-50F – Auger Feed for Powders

This model uses an auger (screw feeder) instead of gravity feed. That’s important for powders and materials that don’t flow freely—things like ground feed, mineral premixes, and fine wood dust. The auger meters material into the bag, and the scale cuts off when it hits the target weight.

Speed is 6-8 bags per minute. Power: 1.5kW for the auger, plus 0.55kW for the scale, plus 0.37kW for the bag clamp.

A feed pellet packing machine in Canada for mash feed often uses this configuration. A feed mill in Quebec uses one to bag their dairy rations. The powder tends to bridge in a gravity hopper, but the auger keeps material moving consistently.

This model also works for fine wood dust and other powders that don’t flow well. If you’re producing something that’s not a clean pellet, the auger feed is usually the right choice.

Price range: $7,500 to $12,000 USD. Stainless steel construction for food-grade applications adds about $2,000-$3,000 to the base price.

DCS-50P – Belt Feed for Mixed Materials

This is the versatile model. It uses a belt feeder, which handles both pellets and powders equally well. If your product line includes both wood pellets and feed pellets, or if you’re running different formulations that vary in flow characteristics, this is the one to look at.

Speed is 6-8 bags per minute. Power: 1.5kW for the belt, plus 0.55kW for the scale, plus 0.37kW for the bag clamp.

An automatic pellet bagging system in Canada at this capacity is common in mid-size pellet plants. A facility in British Columbia uses one to bag both wood fuel pellets and horse bedding pellets. They swap between products by adjusting the belt speed and weight settings. The changeover takes about 10 minutes.

Price range: $8,500 to $14,000 USD. The range reflects whether you need a stainless steel belt for food-grade applications and whether you want the bag conveyor included.

DCS-50P×2 – Twin-Belt System for High Speed

This is the same belt feed design but with two weighing heads running in parallel. One head fills while the other cycles, so you get nearly double the speed. Runs at 10-12 bags per minute.

Power: 1.5kW×2 for the two belts, plus 0.55kW for the scale system, plus 0.37kW for the bag handling.

A biomass pellet bagging system in Canada at this speed is what you’d find in a large commercial operation. A pellet plant in Quebec uses one of these to bag about 6 tons per hour into 40lb bags. They run it about 8 hours a day, and it keeps up with their pellet mill output.

The twin-head design also gives you redundancy. If one head needs maintenance, you can still run on the other at half speed while you fix it.

Price range: $13,000 to $20,000 USD. The higher end includes automated bag placing and a conveyor with built-in sewing head.

DCS-50FB – Stainless Steel for Premixes and Sensitive Materials

This is the stainless steel version of the auger-feed model. It’s designed for premixes, minerals, and any material where corrosion resistance or sanitation is important. The stainless construction prevents rust and makes cleaning easier.

Speed is 6-8 bags per minute. Power: 1.5kW auger, plus 0.55kW scale, plus 0.37kW bag clamp.

A pellet weighing bagging machine in Canada in stainless steel is common in the premix and organic feed sectors. A specialty feed manufacturer in Ontario uses one for their vitamin and mineral premixes. They also use it for their organic chicken feed line, where stainless steel is required for certification.

Price range: $10,000 to $18,000 USD. The wide range reflects whether you need full stainless (hopper, scale, contact parts) or just the material contact surfaces. Full stainless adds about 30-40% over the carbon steel version.

What These Prices Include

When we quote a pellet packing machine in Canada, the base price includes the weighing scale, feed mechanism (gravity, auger, or belt), bag clamp, and basic controls. These are FOB Qingdao ranges. Shipping to Canadian ports, installation, and commissioning are additional.

Bag sealing equipment—sewing heads, heat sealers, or bag conveyors—is typically separate. Add $2,000-$8,000 depending on the sealing method and level of automation.

What Affects the Price?

If you’re comparing automatic pellet bagging system in Canada prices, here’s what creates the ranges:

• Feed type: Gravity feed (DCS-50W, 50K) costs less than auger or belt. Auger and belt cost about the same, but belt gives you more versatility.
• Speed: The twin-head DCS-50P×2 costs about 50% more than a single-head belt model for roughly double the speed.
• Material of construction: Carbon steel is standard. Stainless steel adds 20-40% depending on the scope of stainless components.
• Sealing method: Pre-sewn bags (open-mouth) are the cheapest. If you need to sew bags after filling, add $2,000-$4,000 for a sewing head. If you need heat sealing for plastic bags, add $3,000-$6,000 for a heat sealer.
• Automation: Basic models have manual bag placement—an operator puts the bag on the clamp, the machine fills and releases it. Automated bag placers that feed bags from a magazine add $5,000-$10,000.
• Conveyors: If you need a bag conveyor to move filled bags to palletizing, add $2,000-$5,000 depending on length and whether it’s gravity or powered.

Which Machine for Which Application?

• DCS-50W: Good for small operations, free-flowing pellets. 2-3 bags per minute. Simple and reliable.
• DCS-50K: Faster gravity feed for pellets. 5-6 bags per minute. Common for mid-size pellet plants.
• DCS-50F: Auger feed for powders and materials that don’t flow freely. 6-8 bags per minute.
• DCS-50P: Belt feed—handles both pellets and powders. 6-8 bags per minute. The most versatile single-head option.
• DCS-50P×2: Twin-head belt system for high speed. 10-12 bags per minute. For commercial operations running multiple shifts.
• DCS-50FB: Stainless steel auger for premixes, minerals, and applications requiring corrosion resistance.

Sealing Options

All these models can be configured with different sealing methods:

• Open-mouth bags with sewing: Most common for paper or woven poly bags. The bag is pre-sewn at the bottom; the top is sewn after filling.
• Heat sealing: For plastic or laminated bags. The bag is sealed with heat after filling.
• Mixed sealing: Some customers use heat seal for the bottom, sewing for the top, or vice versa.

The sealing system is usually separate from the scale unit. Tell us what bags you’re using and we’ll spec the right sealer.

With moisture at 45%, you’re going to need drying regardless of which pellet mill for sale Canada you choose. No ring die mill can effectively pellet material that wet—you’d be fighting die binding and poor pellet quality constantly.

For a 3-4 t/h output target, we’d typically recommend an MZLH520 or MZLH678 wood pellet extruder machine in Canada configuration, but you’ll need a rotary dryer upstream sized to handle that same throughput.

The dryer takes your 45% moisture down to about 12-14% before the material hits the mill. We’ve done similar installations in BC where the customer had exactly your raw material mix—spruce and pine sawdust from local mills.

The dryer we spec’d was a φ1.5×15m unit running inlet temps around 400°C. The MZLH520 running at 3-3.5 t/h or the MZLH678 pushing 4 t/h both work well with properly dried fiber. Skip the dryer and you’re looking at maybe 0.5 t/h with constant plugging. Not worth it.

For 15 t/h of wheat straw, I’d lean toward multiple mills. Single large units exist—we make an MZLH768 that can push 6-8 t/h on straw—but you’d need three of them to hit 15 t/h, or two larger custom units. The practical approach we’ve used on the Prairies is running four MZLH678 units or three MZLH768s in parallel.

Why multiple? Redundancy. If one mill needs die change or maintenance, you drop to 75% capacity instead of zero. Also, wheat straw is fibrous and abrasive—spreading the wear across multiple dies gives you better maintenance scheduling.

For a pellet machine line in Canada at this scale, we also need to talk about your bale breaking and grinding setup. You’ll want a heavy-duty bale shredder ahead of hammer mills. For 15 t/h, you’re looking at something like an SFSP66×150 hammer mill or possibly two SFSP66×100s running in parallel.

The whole line—bale breaker, hammer mills, dryers (straw is usually drier, maybe 12-14% if field-dried, but you might still need drying depending on harvest conditions), pellet mills, coolers, and bagging—is a major project. We’ve done several in Saskatchewan and Alberta at this scale.

Eight tons daily at 8 hours gives you about 1 t/h. That’s a good size for a starter organic fertilizer pellet mill in Canada operation. We’d recommend an FZLH320 or FZLH350 depending on how wet your manure is when collected. Fresh layer manure can run 70-75% moisture, so you’ll need solid-liquid separation and drying first.

That’s actually the bigger equipment decision—the pellet mill is the easy part. For 1 t/h of finished fertilizer pellets, you’d likely end up with an FZLH320 (22kW, 2-3 t/h capacity on dry material) running well below its max. That gives you room if you expand later.

The stainless steel version (FZLH320B) is worth considering because poultry manure is corrosive. We’ve done a few of these for Ontario layer operations. The whole line includes a dewatering press, rotary dryer (or a belt dryer if you want gentler handling), the manure pellet mill, cooler, and bagging.

Most customers find the fertilizer pellet market strong enough that the investment pays back in 18-24 months.

For 5,000 head, 6-7 t/h is about right. Feedlot finishing rations typically run 8-10 kg per head per day, so 5,000 head needs about 45-50 tons daily. At 8 operating hours, that’s 5.5-6.25 t/h. Good sizing. For a feed mill in Canada at this scale, we’d recommend an SZLH420 or SZLH508 depending on your exact throughput.

The SZLH420 animal feed granulator (110kW) runs 10-12 t/h on grain-based feeds, so you’d be running it at 60-70% load—ideal for longevity. The SZLH508 (160kW) would be even more conservative. The molasses is the tricky part. We’d spec a molasses mixer (STHJ series) before the pellet mill to distribute it evenly, and we’d use a die with deeper relief to handle the stickiness.

Your grinding setup matters too—corn and barley need different hammer mill screens. We typically recommend an SFSP66×100 or SFSP66×120 hammer mill with screens sized for your target particle size (usually 3-4mm for finishing rations). We’ve done several of these in Alberta—good, solid operations that run 10-12 hours a day.

Same machine, different setup. Alfalfa and canola straw are both forage materials, so the CZLH series is what we typically recommend. A CZLH678 or CZLH768 can handle both, but you’ll want to adjust your die selection and conditioning. Alfalfa has higher protein and mineral content—it’s actually easier to pellet than straw because the natural binders help.

Canola straw is more fibrous and abrasive. You’d want a die with higher chromium content (we recommend 40% chrome or better) for the straw runs. The conditioning parameters also differ—alfalfa likes a bit more steam to soften the leaf material; straw needs less steam but more mechanical shear.

We’ve done dual-purpose lines in Saskatchewan where customers switch between the two depending on market demand. The changeover takes about an hour—die swap, screen change on the hammer mill, conditioning adjustments. Doable, but you need to plan your production schedule accordingly.

A 20 t/h wood pellet processing plant is serious industrial scale. For a pellet factory in Canada that size, total installed power typically runs 2.5-3.5 MW depending on automation level and whether you’re chipping logs or processing pre-chipped sawmill waste. Let’s break it down: you’ll need multiple hammer mills—likely two SFSP66×150 units at 220kW each, plus the main drives on your pellet mills.

For 20 t/h, we’d typically run four MZLH768 units (250kW each) or five MZLH678s (185kW each). That’s 1,000-1,250kW just for the mills. Add dryers—a rotary dryer system with burner and fans adds another 200-300kW. Material handling (bucket elevators, conveyors) adds 100-150kW.

Dust collection systems add another 100-150kW. So total connected power lands around 2.8-3.2MW. You’ll need a service from the utility in the 3.5-4 MVA range to handle startup loads. We’ve done this scale in Quebec and BC. The customer typically works with their local utility to upgrade service before equipment arrives.

For 2 t/h of floating salmon feed, you have options. Single-screw can do it, but twin-screw gives you better control over expansion and oil absorption. For salmon feed specifically, you often want higher oil inclusion (up to 20-25% after coating) and precise expansion control.

A twin-screw extruder like our SPHS120×2 handles that well. Single-screw (SP series) can produce floating feed, but you’ll have less flexibility on formulation changes and oil levels. For a feed plant in Canada focused on aquaculture, we usually recommend twin-screw if the budget allows—it’s more forgiving and gives you room to experiment with different formulations.

That said, if you’re strictly producing one or two recipes and don’t plan to change, single-screw is more economical. The complete line includes grinding (fine grind, 0.6-0.8mm screen), mixing, the extruder itself, a belt dryer (crucial for maintaining pellet integrity), and a coating drum for post-extrusion oil addition.

Total investment for a 2 t/h twin-screw floating fish feed plant with full support equipment runs about $150,000-250,000 USD depending on automation.

Yes, with the right die selection. Mixed softwood is actually the norm in most Canadian operations—very few have a single, consistent species. For a wood pellet press in Canada handling mixed softwood, we recommend a die with 30-40% chrome content.

That gives you good wear resistance without being so hard that it becomes brittle. Pine and fir are similar in density and fiber characteristics; spruce is slightly harder but still within the same family. The bigger variable is moisture content.

If your chips come from different sources with different drying histories, that’s what will cause trouble. We recommend good blending before drying so the dryer sees a consistent feed. In terms of mill sizing, for 10 t/h you’re looking at multiple units—two MZLH768 wood pelletizer machines (3.5-4 t/h each) or three MZLH678s (3-3.5 t/h each) gives you that capacity with redundancy.

We’ve done several plants in BC running exactly this configuration—mixed softwood, two mills, consistent output.

For cattle feed with molasses, paddle mixer is the better choice. Ribbon mixers (SLHY series) work well for dry, free-flowing ingredients. But once you add molasses, the ribbons tend to push material rather than mixing it thoroughly.

Paddle mixers (SLHJ series) use a different action—the paddles lift and tumble material, which handles sticky ingredients better. For a feed plant in Canada running 5 t/h, we’d typically recommend an SLHJ4A (2,000kg batch) or SLHJ6A (3,000kg batch) depending on your batching frequency.

Both handle molasses well when properly maintained. The other option is a continuous molasses mixer (STHJ series) that adds molasses just before pelleting, bypassing the main mixer entirely.

That’s actually the cleaner approach—you mix your dry ingredients in the ribbon or paddle mixer, then the molasses gets added in a separate high-speed mixer right before the pellet mill.

We’ve done both for Manitoba cattle operations. The separate molasses mixer adds about $18,000-25,000 to the line but saves cleaning headaches.

Corn stover is a good bedding pellet raw material—absorbent and readily available. At 12,000 tons annually, assuming 8 operating hours per day, 250 days a year, you’re looking at about 6 t/h.

For a pellet plant in Canada at this scale, you’ll need: a bale breaker or tub grinder to handle the baled stover (corn stover is usually baled), a hammer mill (SFSP66×100 or larger, depending on how fine you need to grind), a dryer (corn stover can be 15-20% moisture at harvest; if you’re storing dry, you might skip this, but many customers still dry to 12% for consistent pelleting), a pellet mill (CZLH678 or CZLH768—forage series), a cooler, a screener, and a bagging system.

Bedding pellets are often 8mm diameter, larger than fuel pellets. The die for that is standard. We’ve done corn stover lines in Ontario and Quebec. The key is the grinding stage—corn stover is fibrous and can wrap around hammer mill rotors if not fed properly. We use a breaker bar configuration in the hammer mill to prevent wrapping.

A 25 t/h feed mill is a major industrial project. Lead time from signed contract to commissioning typically runs 10-14 months. Here’s the breakdown: engineering and design (2-3 months)—this includes layout, steel structure design if needed, electrical, and control systems.

Manufacturing (4-6 months)—we’re building multiple hammer mills (likely three SFSP66×150 units), mixers (SLHJ6A or larger, possibly twin-shaft for faster cycles), pellet mills (three SZLH768 animal feed pellet press units), coolers, screens, and all the material handling equipment. Shipping (1-2 months)—depends on port availability and customs clearance. Installation (2-4 months)—this varies based on whether we’re doing turnkey or the customer handles site prep.

Commissioning (1 month)—getting everything dialed in, training operators. We’ve done this scale before in Quebec and Ontario. The key is good project management and clear communication on site readiness. We don’t have local agents—our team flies in for installation and commissioning, so we need to coordinate tightly with your site schedule.

Thirty tons per day is about 3.75 t/h at 8 hours. Vegetable waste is challenging but doable. The key is moisture and consistency. Fresh vegetable waste can be 80-90% moisture, so you’ll need serious drying. We’ve done similar projects for BC vegetable processors.

The line typically includes: a shredder or grinder to break down the waste, a dewatering press (screw press) to reduce moisture to 60-70%, a belt dryer (gentle handling for fragile material) to bring moisture down to 12-14%, a hammer mill (SFSP series), a mixer if you’re adding other ingredients to balance nutrition, and an animal feed pellet mill (SZLH series).

The final product can be used as cattle feed or even pet food ingredients depending on the formulation. The drying stage is the most expensive part—a belt dryer for this application runs $100,000-200,000 depending on capacity. But if you’re currently paying to landfill that waste, the math often works. We’ve done a few of these for BC and Ontario processors.

A complete 4 t/h wood pellet line with drying and bagging typically runs $170,000-320,000 USD FOB Qingdao. Let me break that down so you see where the range comes from. The pellet mills themselves—either one MZLH768 (about $75,000-85,000) or two MZLH520 wood granulator machines ($55,000-65,000 each) depending on your preference for redundancy.

The rotary dryer (φ1.8×20m) with burner and cyclone runs $50,000-70,000. Hammer mill (SFSP66×100 or ×120) is $5,000-35,000. Cooler, screener, and bagging system add another $25,000-40,000. Conveyors, bucket elevators, and storage bins add $20,000-30,000. Dust collection and controls add $15,000-25,000.

The lower end of the range assumes manual controls, carbon steel construction, and simpler bagging. The higher end includes PLC automation, more stainless components, and a more sophisticated bagging system with sewing head.

Shipping to Canadian ports adds $10,000-20,000 depending on container count. Installation is separate—some customers handle that themselves to save cost.

We can supply motors configured for 480V/60Hz specifically for the North American market. When you order a pellet mill for sale Canada from us, we specify motors rated for 480V, 60Hz, three-phase. That’s standard for our Canadian and US shipments. No step-down transformers needed.

We also supply VFDs (variable frequency drives) rated for your voltage if you want soft-start or speed control capabilities. The control panels are built to North American electrical codes as well—we use UL or CSA listed components when specified.

Just let us know your exact voltage and any specific code requirements (CE, CSA, UL) at the quoting stage. We’ve shipped plenty of equipment to Alberta, BC, Ontario, and Quebec with 480V configurations—it’s our standard for the region.

For alfalfa pellets, you want a consistent grind—not too fine that it creates dust, not too coarse that pellet durability suffers. We typically recommend 4-6mm screens on the hammer mill for alfalfa. At 8 t/h, you’re looking at an SFSP66×120 or SFSP66×150 hammer mill.

The exact screen size depends on your alfalfa type. Leafy third-cutting alfalfa can go with a 4mm screen; stemmier first-cutting might need 6mm to prevent excessive fines. The key is that the grind should be uniform. If you see long fibers in the pellets, your pellet durability will suffer. We’ve done several export-oriented alfalfa lines in Saskatchewan.

They typically run a 5mm screen as a good middle ground. You’ll also want a conditioner on the pellet mill (CZLH series comes with one) to add steam and soften the alfalfa before pelleting. This improves durability without needing to grind too fine.

You’ll need a chipper for the slabs. Hammer mills are designed to process material that’s already reduced to small pieces—typically under 5cm. Hardwood slabs are too large and dense to feed directly. We’d recommend a drum chipper like the XPJ850×500 or larger depending on your slab size.

The chipper reduces slabs to chips in the 20-40mm range. Those chips then go to the hammer mill (SFSP66×100 or larger for 5-8 t/h) for final size reduction to 3-5mm before pelleting. The sawdust can bypass the chipper and go straight to the hammer mill. We’ve done this configuration for sawmills in BC and Quebec—they have both slab waste from the mill and sawdust from the planer.

The two streams merge at the hammer mill infeed. Good blending before the hammer mill gives you consistent feed to the dryer and biomass wood pellet machine.

At 4-5 t/h, 16 hours a day, you’re looking at about 2,000-2,500 operating hours per month (assuming some maintenance downtime). Die life on mixed softwood with a 30-40% chrome die typically runs 1,500-2,500 hours.

So you’d be changing dies every 3-5 months depending on your wood species and how clean it is. Hardwood content reduces die life—oak and maple are more abrasive. Sand and grit in the wood are the biggest killers.

If your sawdust is clean from the mill, you’ll be on the high end. If it’s got bark and dirt mixed in, you’ll be on the low end. For a pellet factory in Canada running those hours, we recommend keeping at least one spare die in stock at all times.

Die reversal (flipping the die to wear the other side) can extend life by 20-30%. We also offer die reconditioning services—send us your worn die and we’ll machine it back to spec.

For 2-3 t/h, you’re looking at a starter commercial line. We’d recommend an MZLH520 pellet mill (90kW, 1.0-1.2 t/h on wood) or MZLH678 (185kW, 2.5-3.0 t/h). For your target, the MZLH678 gives you room to grow.

Complete line includes: a hammer mill (SFSP66×80 or ×100 depending on chip size), a dryer (φ1.5×15m or φ1.2×12m depending on incoming moisture), the pellet mill, cooler, and bagging if you’re selling excess. Total investment for a 2-3 t/h line runs $95,000-160,000 USD for the main equipment.

If your chips are already dry (under 20% moisture), you can skip the dryer and save $30,000-40,000. We’ve done a few greenhouse operations in Ontario—they typically run the line in fall and winter when heating demand is high, and sell extra pellets to other greenhouses or farm stores.

We don’t handle permitting directly—that’s the customer’s responsibility with their local municipality and provincial environment ministry. But we can help by providing detailed equipment specs, emissions data, and noise level information that you’ll need for your permit applications.

For a biomass pellet making machine in Canada near residential areas, the key issues are dust control and noise. We specify cyclones and pulse-jet baghouses to keep particulate emissions low. We can also provide acoustic enclosures for the pellet mill and hammer mill—those are the noisiest pieces. We’ve done installations in Ontario and Quebec where the plant was within a few hundred meters of homes.

The regulators typically want to see: a dust collection system with 99%+ efficiency, enclosed material handling, and sound attenuation on the main equipment. We’ve provided the technical data for these applications successfully. Just be aware that the permitting process can take 6-12 months depending on the jurisdiction.

Yes, with the same mill but different dies. The changeover takes about 30-45 minutes on an MZLH series biomass fuel pellet machine. You’ll need two dies—one for 6mm, one for 8mm. The 8mm die usually runs at slightly higher throughput because of the larger hole diameter.

The other adjustment is cutter speed—you’ll want longer pellets for bedding (25-40mm) versus shorter for fuel (15-25mm). Most customers running dual products schedule their production in batches: run fuel for a week, swap dies, run bedding for a week. We’ve done this for several Canadian operations.

One in Ontario runs fuel in winter (heating season) and switches to bedding in spring for the horse market. Works well. Just keep the dies properly maintained and lubricated between runs.

For a 15 t/h feed mill, the difference is substantial. A manual system with push-button controls, basic batching, and minimal automation runs about $240,000-320,000 USD for the main equipment. A fully automated system with PLC controls, recipe management, automated batching, moisture sensors, and remote monitoring runs $380,000-550,000 USD.

That’s just the equipment—not including installation. What you get for the extra cost: consistent batching accuracy (±0.1% vs ±0.5%), reduced labor (one operator can run the whole plant), better traceability (good for quality programs), and typically lower energy use because the system optimizes motor starts.

For a 15 t/h feed plant in Canada, most commercial operations go with automation. The payback on labor savings alone is usually 2-3 years. Manual systems are more common for seasonal operations or customers with existing labor they can redeploy.

Flax straw is harder to pellet. It has higher oil content and longer fibers. Canola straw is more straightforward—fibrous but similar to wheat straw. For both, you’ll want a CZLH series pellet mill (forage series) with a die that has higher chrome content (40%+) to handle the abrasion.

The grinding stage is critical. Flax straw tends to wrap around hammer mill shafts if the mill isn’t configured correctly. We recommend a hammer mill with a “wrap guard” or breaker bar configuration—basically a plate that prevents long fibers from winding around the rotor. For canola straw, standard hammer mill configuration works fine.

Throughput will be lower on flax—maybe 70% of what you’d get from canola at the same power. Both are viable bedding pellet raw materials. We’ve done lines for both in Saskatchewan. If you have access to both, I’d focus on canola first to get your process dialed in.

If your wood shavings are kiln-dried to under 15% moisture, you can skip the dryer. Kiln-dried material is typically 8-12% moisture, which is perfect for pelleting. That saves you $30,000-50,000 on the line and reduces your energy costs significantly.

For a 3 t/h bedding line, we’d recommend an MZLH520 (90kW, 1.0-1.2 t/h) or MZLH678 (185kW, 2.5-3.0 t/h). The MZLH678 would run at about 60-70% capacity, which is good for longevity. The rest of the line: a hammer mill (SFSP66×80 or ×100) to reduce shavings to the right particle size—bedding pellets usually want 6-8mm grind, not as fine as fuel pellets.

Then the pellet mill, cooler, screener, and bagging. Total investment for a 3 t/h line without dryer runs $80,000-120,000 USD depending on automation. We’ve done several of these for sawmills in BC and Quebec that already had kiln-dried waste.

A 10 t/h wood pellet factory typically consumes 200-250 kWh per finished ton. So at full capacity, you’re looking at 2,000-2,500 kWh per hour. Multiply by your operating hours and local electricity rate. Let’s break down where that power goes: drying is the biggest consumer—the rotary dryer’s burner fan and drum drive take about 80-100 kWh per ton.

The pellet mills (likely two MZLH768s at 250kW each) account for 50 kWh per ton total when running at capacity. Hammer mills (SFSP66×120 or similar) take 25-30 kWh per ton. Material handling (bucket elevators, conveyors) adds 15-20 kWh per ton.

Dust collection and fans add another 20-30 kWh per ton. So if you’re running 8 hours a day at 10 t/h, you’re looking at about 16,000-20,000 kWh daily. At $0.10-0.15 per kWh (typical industrial rates in most Canadian provinces), that’s $1,600-3,000 per day in electricity. Natural gas for drying is a separate cost—typically another $10-20 per ton depending on gas prices.

Five tons per day is about 0.6 t/h at 8 hours. Yes, we can handle that. Fish waste is high in protein and oil—good raw material for feed. The challenge is freshness and consistency. You’ll need a grinder or emulsifier to break down the waste into a paste, then mix it with dry ingredients (soy, wheat, etc.) to balance the formulation.

The extruder (SPHS series twin-screw) can handle up to 30-40% wet ingredients in the mix. You’ll also need a dryer after extrusion—fish-based feed is prone to spoilage if moisture isn’t controlled. A small belt dryer (QHG-500 or similar) works well for this capacity.

The complete line for 0.5-0.8 t/h runs about $120,000-180,000 USD depending on automation. We’ve done a few of these in BC for fish processors who wanted to close the loop on their waste streams. The regulatory side matters—you’ll need approval to use fish waste for feed, but the demand for high-protein aquaculture feed is strong.

Not necessarily. At 500 acres, assuming 3-4 tons per acre, you’re harvesting 1,500-2,000 tons annually. A 1-2 t/h line running 8 hours a day for 100-150 days (your post-harvest window) can process that. The key is whether you have the storage space for raw hay and finished pellets.

For a pellet plant in Canada at this scale, we’d recommend a CZLH420 (90kW, 1.8-2.0 t/h on forage) or CZLH520 (132kW, 2.8-3.0 t/h) if you want room to grow. Total investment runs $80,000-150,000 depending on whether you need a dryer (hay is usually 12-15% moisture, so you can often skip it). We’ve done several farm-scale forage lines in Ontario and Quebec.

They run hard for a few months, then sit idle. That’s fine—just keep the equipment maintained and protected from moisture during off-season. Many farmers also offer custom pelleting services to neighbors during slower periods to generate extra revenue.

Cooling time isn’t a set number—it’s about temperature. You want pellets at ambient temperature before bagging, typically under 30°C. In a counterflow cooler (SKLN series), pellets pass through a column where ambient air is pulled up through them. Residence time is usually 10-20 minutes depending on pellet temperature coming out of the mill (75-85°C).

The key is that the cooler is sized correctly. For a 4 t/h line, an SKLN20×20 or SKLN24×24 does the job. If you bag pellets that are still warm, you’ll get condensation inside the bag, which leads to mold and customer complaints.

We always recommend a cooler with a temperature probe so operators can verify pellets are cooled before bagging. In cold Canadian winters, you actually might overcool—pellets coming out of the cooler can be below freezing, which is fine for bagging as long as there’s no condensation from indoor humidity.

Oat hulls and wheat straw are both abrasive, but for different reasons. Oat hulls have high silica content—that’s hard on dies. Wheat straw is fibrous but less abrasive. For this mix, we’d recommend a die with 40-50% chrome content, which is a harder alloy than the standard 30% we use for wood.

The higher chrome content resists the abrasive wear from silica. The trade-off is that higher chrome dies are more brittle, so you need to be careful with foreign objects (stones, metal) that can crack them. We’d also recommend a magnetic separator on the infeed to catch any metal. The conditioning system matters too—steam helps lubricate the die, reducing wear.

For 8 t/h on these materials, you’re looking at multiple CZLH768 units (maybe three running at 2.5-3 t/h each) or two larger custom units. We’ve done oat hull lines in Ontario where the customer had similar concerns. With the right die, they got 1,500-2,000 hours per die, which they found acceptable given the material cost savings.

Silica in alfalfa is a wear issue, but manageable. The key is to use a hammer mill with replaceable wear plates and hard-faced hammers. For alfalfa processing, we recommend the SFSP series with “hard-facing” on the hammers—basically a weld overlay that resists abrasion.

We also offer tungsten carbide hammers for the most abrasive applications, though that adds cost. The screen will wear faster too, so keep spares. In terms of configuration, running a slightly larger screen (4-5mm instead of 3mm) reduces hammer tip speed relative to the material and can extend wear life.

We’ve installed several alfalfa lines in Saskatchewan and Alberta. Typical hammer life on alfalfa is 500-800 hours before re-facing; screens last 1,000-1,500 hours. It’s higher wear than corn or wheat, but the value of the finished product justifies the maintenance costs. We recommend keeping a log of hammer wear so you can plan maintenance around production windows.

A 40 t/h complete feed mill plant is a substantial facility. Typical building footprint for the main production area runs 1,500-2,500 square meters, plus raw material storage and finished product storage. Here’s the breakdown: raw material intake and cleaning—200-300 sq m.

Batching and mixing area (multiple bins, scales, mixers)—300-400 sq m. Grinding area (multiple hammer mills)—200-300 sq m. Pelleting area (multiple pellet mills, conditioners)—300-400 sq m. Cooling, screening, and coating—200-300 sq m.

Bagging and bulk loadout—200-300 sq m. Plus you’ll need ingredient silos or bins outside the main building. Total site area including truck access and staging is often 5,000-10,000 sq m. For a 40 t/h feed plant in Canada, we’ve done projects in Manitoba and Ontario.

The building height needs to accommodate bucket elevators and silos—typically 15-20 meters at the tallest point. Good material flow design is critical at this scale; material should move in one direction from intake to finished product without cross-traffic.

Two percent oil can go either way, but each has trade-offs. Adding oil in the mixer (before pelleting) lubricates the die, which can increase throughput and reduce die wear. However, too much oil in the mix can cause the pellets to slip in the die and not form properly.

For 2%, you’re fine—that’s below the threshold where problems start (usually 3-4%). Adding oil after pelleting (in a coating drum) gives you more flexibility on oil percentage and ensures pellet formation isn’t affected.

The downside is you need a separate coater. For a feed plant in Canada that might vary oil levels across different rations, we usually recommend post-pelleting coating. That way you can run high-oil finishing rations without affecting pellet quality.

The STZJ series coating drums we supply are designed for this—they tumble pellets and spray oil evenly. If you’re set on mixing before pelleting, just know that oil can degrade over time in the mixer and may affect pellet durability.

Fifty thousand tons annually at 250 operating days gives you 200 tons per day. At 16 hours per day (two shifts), that’s 12.5 t/h. At 24 hours, it’s about 8.3 t/h. Most plants run 16-20 hours to allow for maintenance. So you’re looking at 10-12 t/h capacity.

For a pellet factory in Canada at this scale, we’d recommend four MZLH768 units (250kW each, 3.5-4 t/h each) or five MZLH678s (185kW each, 2.5-3 t/h each). The multi-mill approach gives you redundancy—if one goes down, you’re still at 75-80% capacity.

You’ll also need a chipper or hammer mill setup sized for your raw material, a rotary dryer (φ1.8×24m or larger), coolers, and bulk storage. Total investment for a 10-12 t/h turnkey plant runs $900,000-1,500,000 USD depending on automation and whether you need chipping capability.

The big cost drivers are the dryer, the multiple pellet mills, and the material handling system (conveyors, elevators, bins). We’ve done this scale for several BC and Quebec operations supplying power plants.

Eighteen to twenty percent is borderline. On the high side, but sometimes doable depending on your wood species and the pellet mill. For softwoods (pine, spruce), 15% is the practical max for consistent operation. At 18-20%, you’ll have more die binding, higher energy use, and lower throughput. For hardwoods, even 15% is pushing it.

If your chips are consistently at 18% and you’re processing softwood, you might get away with it if you run the mill at lower throughput (maybe 70-80% of rated capacity) and keep the die warm. But if the moisture varies at all—and it usually does—you’ll have trouble.

For a pellet mill for sale Canada, we generally recommend a dryer for anything over 15% moisture. A small dryer (φ1.2×12m) adds $25,000-35,000 to the line but saves you a lot of operational headaches. We’ve seen customers try to skip the dryer and end up adding it later—costing more in downtime and lost production than if they’d bought it upfront.

Yes, but you need to size the generator properly. A pellet mill motor (say 250kW on an MZLH768) has a high starting current—up to 6-8 times running current for a few seconds. You can mitigate this with a VFD (variable frequency drive) for soft-start, which reduces starting current to maybe 2-3 times running.

For a 250kW motor, with VFD, you’d need a generator rated for 500-600 kVA to handle the startup. For the whole plant—hammer mill, dryer fans, conveyors—you’re looking at 1.5-2 MW generator capacity for a 4-5 t/h line.

The other consideration is power quality. Generators can have frequency fluctuations that affect VFDs and controls. We’d recommend a generator with electronic governor and automatic voltage regulation. We’ve done off-grid installations in northern BC where grid power wasn’t available.

They use diesel gen-sets sized for the full plant load plus 25% margin. Fuel consumption is significant—about 200-300 liters per hour for a 4 t/h plant. Worth running the numbers on fuel cost versus grid connection cost.

Sinking feed requires lower expansion than floating feed. In extrusion, expansion is controlled by the die design, screw configuration, and moisture content. For sinking feed, you use a die with smaller holes and less open area, and you run the extruder with less shear (lower screw speed, different screw elements). The formulation matters too—sinking feed typically has higher protein and lower starch.

For a feed plant in Canada producing both types, a twin-screw extruder (SPHS series) gives you the flexibility to switch between them by adjusting screw configuration and die selection. Changeover takes about an hour. The downstream drying and coating processes are similar—belt dryer, then oil coating if needed.

For sturgeon feed specifically, pellet durability matters because sturgeon take longer to eat than some species. We recommend a vacuum coater for oil application to ensure pellets are fully saturated and stable in water.

At 5,000 hours per year, the mill itself will last 15-20 years with proper maintenance. The wear parts are the main consumables. For the MZLH series, the ring die is the primary wear item—1,500-2,500 hours depending on wood species and cleanliness. Roller shells also wear—replace every 800-1,200 hours.

The bearings in the mill head should be replaced every 8,000-10,000 hours as preventive maintenance. The gearbox, if properly lubricated, will outlast the rest of the mill.

So for a biomass pellet mill in Canada running heavy hours, you’re looking at 2-3 die changes per year, 4-6 roller shell changes per year, and a major bearing service every 2 years.

We keep these parts in stock and can ship quickly. The mill itself—the main casting, shaft, gearbox—is built to last decades. We have customers with MZLH mills from 15 years ago still running original gearboxes.

A semi-automatic bagging line for 4 t/h runs $15,000-35,000 USD depending on speed and features. At 4 t/h in 40lb bags, you’re looking at about 220 bags per hour. A DCS-50K gravity-feed bagger (5-6 bags/min) would handle that easily—that’s $6,500-10,000.

You’ll need a bag conveyor ($2,000-5,000), a sewing head or heat sealer ($2,000-4,000), and a palletizer station—either manual ($1,000-2,000 for a scale and roller conveyor) or semi-automatic with a pallet stacker ($5,000-10,000).

If you want a fully automatic system with bag placer, that adds $10,000-20,000. For most Canadian operations, semi-automatic (operator places bag on spout, machine fills and releases, conveyor moves to sewing station) is the sweet spot. One operator can handle the whole line at 4 t/h.

We’ve added bagging lines to existing pellet plants across Canada—it’s usually a straightforward retrofit.

We ship from our factory in China to Canadian ports—typically Vancouver for western Canada, Halifax or Montreal for eastern. For northern Alberta, Vancouver is the closest major port. Shipping is by container (20ft or 40ft) depending on equipment size.

A 4 t/h pellet line with dryer might fill 3-4 containers. Freight cost from our factory to Vancouver runs $3,000-6,000 per container depending on volume and current rates. From Vancouver to northern Alberta, you’ll need trucking—add $3,000-8,000 depending on distance and if you need flatbed or step-deck trailers for oversize items (dryer drums, large bins).

Total freight for a 4 t/h line to northern Alberta might be $15,000-25,000. For larger plants, freight costs scale. We can recommend freight forwarders who handle Canadian customs clearance and inland trucking. Some customers arrange their own shipping to save cost. We’re happy to work either way. The key is planning ahead—shipping from China to Vancouver takes 4-6 weeks, plus customs clearance.

Steam conditioning for a 12 t/h alfalfa line consumes about 600-800 liters per hour of water (for steam generation). That’s assuming 5-6% steam addition by weight, which is typical for alfalfa. The water goes into the product as steam and then is removed in the dryer.

So it’s not a consumptive use in the sense of wastewater—it’s evaporated. For a feed plant in Canada, you’ll need a boiler to generate the steam. For 12 t/h, a 2-3 ton per hour boiler is appropriate. Boiler water treatment is important to prevent scale in the conditioning system.

If you’re in an area with hard water, you’ll need a water softener. We can provide the conditioning system with your pellet mills (CZLH series) sized for your steam needs.

Some operations also recapture condensate to reduce water use, but that’s more common in larger facilities. For a 12 t/h line, the water cost is negligible compared to the value of the finished product.

Manufacturing lead time for a single pellet mill (MZLH, CZLH, SZLH, or FZLH series) is typically 4-8 weeks depending on our order backlog and whether it’s a standard size or custom configuration. Shipping to Vancouver or Halifax takes 4-6 weeks by sea. So total time from order to port arrival is 8-14 weeks.

Customs clearance adds 1-2 weeks. If you need installation support, we schedule our team to arrive once equipment is on-site. For a complete line with multiple pieces (dryer, hammer mill, conveyors, etc.), lead time extends to 12-20 weeks because of the longer manufacturing time for custom-fabricated items like the dryer.

We recommend ordering at least 6 months before your target startup date to allow for manufacturing, shipping, installation, and commissioning. Rush orders are possible but add cost. We’ve shipped many pellet mills for sale Canada over the years, and the timeline is predictable if we plan together.

When Canadian customers come to us for a pellet mill for sale Canada, they usually have a pretty clear picture of their raw material and target output. But the actual project design—that’s where our engineering team earns their keep. Every site is different. Every raw material behaves differently. What works for a sawmill in British Columbia might not work for a forestry operation in Quebec.

Let me walk you through an actual wood pellet plant construction project we completed in late 2022. It’s a good example of how we take a customer’s requirements and turn them into a working pellet plant in Canada.

The Customer Inquiry

Back in November 2022, we got an inquiry that started like this:

*”Hi, we would like to have a quotation regarding wood pellet machinery. We use wood residues from hard trees, sawdust, and log trees that are not suitable for lumber as raw material. Moisture is around 45%. We need 3 tons or more per hour capacity. We intend to operate 8 hours a day, 6 days a week. The product will go into 15 kg bags, but we could also consider the option of large one-ton bags. Thank you.”*

That’s the kind of inquiry we like—specific, realistic, and clearly thought through. The customer knew their raw material, their moisture content, and their operating schedule. That made the engineering work a lot easier.

The Project at a Glance

We signed the contract on December 6, 2022. The project was a 3-3.5 t/h wood pellet line. Total investment came to about $300,000 USD. The plant occupies 2,600 square meters of building area.

Annual output is around 15,500 tons of biomass pellets. They run 300 days a year, 8 hours a day, with 10 employees total. That’s the kind of efficiency a well-designed biomass pellet mill in Canada can deliver—good throughput with minimal labor.

Equipment Configuration

This wasn’t just a single machine. It’s a complete pellet production line in Canada with all the supporting equipment sized to match:

Two MZLH520 pellet mills running in parallel gives them redundancy—if one needs maintenance, they can still run at half capacity. That’s the kind of practical engineering that comes from experience with industrial pellet mill in Canada installations.

The Process Flow

The whole line breaks down into three sections:

1. Raw Material Pretreatment

Hardwood logs, slabs, and sawdust come in. The wood chipper breaks the larger pieces down. Then the hammer mill reduces everything to under 5mm. The rotary dryer takes moisture from 45% down to 12-15%—critical for good pellet quality. A 40m³ storage bin with a bucket elevator buffers material between drying and pelleting.

2. Pelleting Section

Material feeds into the two MZLH520 mills. Each has its own conditioning system to add steam and bind the material. The dies are sized for 6mm wood pellets—standard for both residential and industrial fuel. The cutter on each mill adjusts the pellet length automatically.

3. Cooling, Screening, and Packaging

Pellets come out of the mills at 75-85°C. Too hot to bag. The cooler drops them to near ambient temperature. The vibrating screener separates fines—they go back to the hammer mill for another pass. Good pellets go to the DCS-50 packing machine, which bags them in either 15kg bags or one-ton bulk bags depending on the order.

What Made This Project Work

The customer’s raw material is mixed hardwood—oak, maple, and some birch. Hardwood is denser than softwood and requires more grinding power. We upsized the hammer mill from what we’d normally spec for softwood. The dies on the MZLH520 mills are a harder alloy to handle the abrasion. Small details, but they make the difference between a line that runs reliably and one that’s constantly down for die changes.

The site layout also took some thinking. The plant sits on a rectangular lot with other factories to the north and south, open space to the west and east. We arranged the equipment so raw material comes in on the west side, finished product leaves on the east. Forklifts move material inside—no need for a truck dock. Simple, but efficient.

Why This Configuration

This isn’t a one-size-fits-all pellet factory in Canada setup. The equipment list changes based on the raw material:

• If the customer had started with clean sawdust instead of logs and slabs, we could have skipped the chipper.
• If the moisture had been under 20%, we might have recommended no dryer at all.
• If they wanted higher automation, we’d add more conveyors and a PLC system with remote monitoring.

Every ring die pellet mill in Canada project we do is custom. The customer’s operating schedule, labor availability, and building constraints all feed into the final design. That’s why we start every project with a detailed conversation about the raw material—not just what it is, but what condition it arrives in.

The Bigger Picture

Canada continues to be one of the world’s leading producers and exporters of wood pellets. The market for industrial-grade biomass keeps growing, and domestic demand for residential heating pellets stays steady. For anyone looking at a pellet manufacturing equipment in Canada project, the fundamentals are solid.

We’ve now done projects across the country—from small 1 t/h lines for farms to large industrial plants shipping container loads. Each one is different, but the approach is the same: start with the raw material, design around the customer’s operating reality, and build equipment that runs reliably day after day.

Have a Project in Mind?

If you’re thinking about setting up a pellet production machine in Canada, we’d like to hear about your raw material. Hardwood, softwood, sawdust, slabs? What moisture? What’s your target output? Send us the details and we’ll put together a custom proposal—just like we did for this customer.

When a customer comes to us looking for a pellet mill for sale Canada, we don’t just ship them a machine. We figure out how their raw material behaves, how their facility is laid out, and what their operating schedule looks like. Every project is different. Here’s one we completed back in 2018—it’s a good example of how we take an existing building, a specific raw material mix, and turn it into a working pellet plant in Canada.

The Project at a Glance

This project was signed on August 3, 2018. The customer needed a 2-2.5 t/h wood pellet line. Total investment started around $200,000 USD. Installation took 45 days.

Annual output is about 12,000 tons of wood fuel pellets. Raw material consumption breaks down to roughly 2,000 tons of wood chips, 3,000 tons of sawdust, and 7,000 tons of wood scraps—about 12,000 tons total input. Power consumption runs about 150,000 kWh per year, water consumption around 800 tons annually.

The pellet size requirement was 8-10mm, which is larger than the standard 6mm fuel pellet. That’s for a specific industrial customer—some biomass boilers prefer larger pellets because they burn slower.

The Raw Material

The customer works with 50% moisture wood chips and 50% moisture sawdust. That’s fairly wet—anything over 40% needs serious drying before pelleting. The mix is a combination of clean wood waste from sawmills and some scrap material. Having two different raw material types with similar moisture meant we could design a single drying system that handles both.

Equipment Configuration

This is a complete biomass pellet mill in Canada setup with everything sized to match the 2-2.5 t/h target:

Total installed power is 385kW. The single MZLH520 ring die pellet mill in Canada is sized to run 8 hours a day, 6 days a week—about 2,500 operating hours annually. For a pellet factory in Canada at this scale, that’s a reasonable schedule.

Facility Layout

This project was interesting because the customer already had an existing abandoned workshop. Instead of building new, we designed around what they had. Total area is about 4,000 square meters.

The building is a convex shape. The entrance is at the northwest corner. Raw material storage sits in the north section—about 500 square meters of covered space for incoming chips, sawdust, and scraps. The crushing workshop is a 200 square meter steel-frame structure adjacent to the raw material area.

Production area is 600 square meters on the first floor. Finished product storage is 300 square meters in the west section. The semi-finished product area—where material sits between drying and pelleting—is 1,000 square meters in the center of the building. That’s a buffer zone so the dryer and pellet mill don’t have to run at exactly the same rate.

The east side of the building is vacant—room to expand later if they want. There’s an 80 square meter office, and a 500 square meter parking and loading area. Good layout for material flow: raw material comes in the north, moves south through processing, finished product loads out the west.

Process Design

The process breaks down into six main steps:

1. Chipping

The wood scraps—larger pieces and slabwood—go through the JLBX-216 chipper first. This breaks them down into smaller flakes and rods that the hammer mill can handle. The chips and sawdust go straight to the next step.

2. Crushing

The SFSP66×80 hammer mill runs in a fully enclosed crushing workshop. There’s a suction port on top that pulls dust into the pulse dust collector under negative pressure. That’s critical—wood dust is a fire hazard and a health concern. The hammer mill reduces everything to powder fine enough to pass through whatever screen size we set.

3. Drying

The φ1.5×15m rotary dryer handles the 50% moisture material and brings it down to about 12-15% before pelleting. The dryer is the most energy-intensive piece in the line, but with wet feedstock you don’t have a choice.

4. Pelleting

Material from the storage bin feeds into the MZLH520 pellet mill. The ring die is sized for 8-10mm pellets—larger than standard fuel pellets. The customer wanted this size for a specific industrial boiler customer. The die alloy is a harder grade to handle the hardwood content in their mix.

5. Cooling

Pellets come out of the mill at around 75-85°C. The SKLN14×14 counterflow cooler pulls air through the pellets, dropping them to near ambient temperature. If you bag hot pellets, you get condensation inside the bag, which ruins the product.

6. Screening and Packaging

The vibrating screen separates fines from whole pellets. Fines go back to the hammer mill for another pass. Good pellets go to the DCS-50 packing machine, which bags them in woven bags with the sewing head sealing them closed.

Why This Configuration Worked

The customer had a few specific constraints. They had an existing building, not a greenfield site. They had two different raw material types—sawdust and chips—both at similar moisture. They needed 8-10mm pellets, not the standard 6mm.

We sized the dryer for the wetter material and made sure the hammer mill had enough capacity to handle the chips after chipping. The single MZLH520 mill is enough for 2-2.5 t/h when running 8mm die. If they ever want to switch to 6mm pellets, they’d get slightly higher throughput.

The layout uses the existing building’s shape—raw material north, finished product west. Material moves in one direction, no backtracking. The vacant east side gives them room to add a second pellet mill if they decide to expand later.

A Note on Canadian Market

Wood pellet production in Canada has grown steadily over the past decade. The number of producers is still relatively small compared to Europe or the US, which means there’s room for new entrants. Pellets burn cleaner than coal, and the carbon accounting works out favorably for biomass. Whether you’re targeting the domestic heating market or export, the demand is there.

This pellet production machine in Canada project was designed for export-grade pellets. Quality requirements were high—consistent size, low fines, good durability. The customer had to meet the specifications their overseas buyers demanded. That meant paying attention to die selection, cooling, and screening.

Over the years, we’ve built a lot of pellet plants. Not just in Canada—across North America, Europe, Asia, and beyond. Every project is different because every raw material is different, every customer’s facility is different, and every market has its own requirements. But what ties them together is the same approach: start with the raw material, design around the customer’s reality, and build equipment that runs reliably.

When someone comes to us looking for a pellet mill for sale Canada, they’re not just buying a machine. They’re buying a production line that fits their specific situation. And we’ve got the track record to prove we know how to do that.

Recent Projects Across the Globe

Here’s a sample of pellet plant projects we’ve completed in the last few years. Each one had its own challenges—different raw materials, different scales, different end markets:

What you won’t see in that list are the dozens of smaller projects—the 0.5 t/h starter lines, the farm-scale setups, the custom configurations for unusual raw materials. Those don’t always make the project list, but they’re just as important. Every project teaches us something about how different materials behave under pressure.

Why the Wood Pellet Market Is Growing

There’s a reason we’re seeing more inquiries for wood pellet mill in Canada and everywhere else. The wood pellet industry has some real advantages right now:

Raw material availability. Forestry residues, sawmill waste, and dedicated energy crops are abundant in many regions. In Canada alone, there are millions of tons of sawdust and wood chips that are currently underutilized.

Mature equipment technology. The wood pellet manufacturing equipment has been refined over decades. A modern ring die pellet mill in Canada is reliable, efficient, and can run for thousands of hours between major maintenance. That wasn’t always the case.

Policy support. Governments around the world are looking for alternatives to coal. Biomass pellets qualify as renewable energy in many jurisdictions, which means incentives for production and consumption.

Market demand. The numbers speak for themselves. Global wood pellet trade has grown steadily. European markets import millions of tons annually. Domestic heating markets in North America are expanding. Profit margins, while variable, are attractive enough to draw new investors.

Carbon accounting. Pellets from sustainably managed forests have a favorable carbon footprint. That matters to utilities, to industrial buyers, and increasingly to retail consumers.

What This Means for Canadian Producers

Canada is already a major player in the global wood pellet market. The forestry infrastructure is there. The raw material is there. The export infrastructure—ports on both coasts—is there. For anyone looking at a pellet factory in Canada, the fundamentals are solid.

What we’re seeing now is a shift. The early plants were large-scale industrial facilities shipping container loads to Europe. Now we’re seeing mid-size plants serving regional heating markets, small farm-scale operations processing their own waste, and specialty producers targeting niche markets like horse bedding or barbecue pellets.

That’s where a pellet production machine in Canada doesn’t have to be huge to be profitable. A 1-2 t/h line running 8 hours a day can produce enough to supply a regional market. The key is getting the equipment right for your specific raw material.

What We Bring to the Table

When we work with a customer on a pellet manufacturing equipment in Canada project, we’re not just shipping a box of machines. We’re designing a system that works with their specific raw material, their facility, and their operating schedule.

That means we ask a lot of questions up front. What are you processing? Sawdust, wood chips, slabs? What’s the moisture content? Is it consistent or does it vary? What’s your target throughput? Are you bagging pellets or shipping bulk? What’s your power supply? What’s your labor situation?

The answers change the design. High-moisture material needs a bigger dryer. Mixed raw materials need flexibility in the grinding section. Limited floor space might mean a different layout. Low labor availability means more automation.

That’s the difference between a pelletizer for sale Canada that’s just a machine and a pellet plant in Canada that actually works for your business.

Looking Ahead

The wood pellet market isn’t going away. The demand for renewable, storable, carbon-neutral fuel is only going to grow. Whether you’re in Canada, the US, Europe, or anywhere else, the opportunity is there.

If you’re thinking about entering the wood pellet industry—or expanding an existing operation—we’d like to talk. Tell us about your raw material, your target output, and your facility. We’ll put together a proposal based on what we’ve actually built, not just what we can sell.

When someone asks about a pellet mill for sale Canada, they’re usually thinking about the machine itself. But the reality is, a pellet plant is more than just a mill. It’s a system. And getting that system right takes more than just shipping equipment. Over the past 25 years, we’ve learned that the service side—the design, the planning, the installation, the follow-up—is what separates a project that works from one that struggles.

Here’s how we approach a pellet plant in Canada project from start to finish.

Personalized Customization & 3D Renderings

We don’t have a standard layout that we drop into every site. Every customer has different raw materials, different building constraints, different throughput targets. So we start by figuring out what you actually need.

Some customers come to us with a clear idea of what they want. Others are still figuring it out. We help both. We’ll sit down with you, go through your raw material, your site, your operating schedule, and your budget. Then we put together a proposal that matches your situation.

Once we have a concept, we provide 3D renderings of the layout. That way you can see how the equipment fits together, how material flows through the building, where the operators will stand. It’s a lot easier to spot problems in a rendering than after the concrete is poured.

This matters especially for a biomass pellet mill in Canada project where space might be tight, or where you’re fitting equipment into an existing building. We’ve done projects where we had to work around support columns, low ceilings, and odd-shaped rooms. The renderings help us get it right before we ship anything.

On-Site Investigation & Local Adaptation

We don’t design projects from a desk halfway around the world. When it makes sense, we send people to the site. They look at the building. They look at where the raw material comes in. They look at where the finished product needs to go. They talk to the people who will be running the equipment.

Different sites demand different solutions. A pellet factory in Canada in the middle of a forestry region might have different power availability than one near a city. A site with cold winters needs different building insulation than one in a milder climate. A facility with limited truck access might need a different material handling setup.

We adapt. The design changes based on what we find on the ground. That’s how you end up with a pellet production machine in Canada setup that actually works in your specific situation, not just on paper.

Professional Team & Door-to-Door Installation

We’ve been doing this for 25 years. Our technical team has seen pretty much every problem you can imagine. They’ve installed equipment in every kind of building, in every kind of weather, with every kind of site constraint.

We manage installation as a unified team. Same training, same standards, same quality control. No subcontractors who show up and do things their own way. When our guys are on site, they know what needs to happen and how to do it.

Installation is where a lot of projects go sideways. A ring die pellet mill in Canada is heavy equipment. It needs to be leveled correctly, aligned properly, and connected to the right power and controls. Get any of that wrong and you’re chasing problems for months. Our team makes sure it’s right from the start.

Technical Service & Whole-Process Guarantee

Service doesn’t start after the equipment is running. It starts the day we start talking.

Pre-sale, we’re available to answer questions about capacity, raw material suitability, layout options. We’ve been doing this long enough to know what questions to ask—questions you might not even know you should be asking.

After the sale, we’re still there. 24-hour technical support. If something breaks, we help you figure out what happened and how to fix it. If production isn’t hitting targets, we work with you to find out why.

For a pellet manufacturing equipment in Canada project, that ongoing support is critical. You’re not just buying a machine. You’re buying the confidence that when something comes up—and something always comes up—there’s someone to call who knows your system.

One-to-One Guidance & Worry-Free Production

Once the equipment is installed and running, we don’t just pack up and leave. We stay long enough to make sure your operators know how to run the line.

That means hands-on training. We show them how to start up the pellet press machine in Canada, how to adjust the dies, how to change screens on the hammer mill, how to read the control panel. We stay until they’re comfortable running it themselves.

Some customers have experienced operators. Some have never run a pellet line before. Either way, we adapt the training to match. We’ve had projects where we trained a single operator who ran the whole line. We’ve had projects where we trained a full crew. The approach changes, but the goal is the same: you should be able to run the line without us.

Quick Response & Lifetime Maintenance

Equipment wears out. It’s just the nature of the business. Dies wear. Hammers wear. Bearings eventually need replacement.

We support our equipment for the life of the machine. Warranty period is one thing. But we don’t stop supporting after that. As long as the equipment is running, we’re available to help.

When problems come up, we respond fast. First response is immediate. We figure out what’s going on, then we figure out how to fix it. Sometimes it’s a phone call and a replacement part. Sometimes it’s a site visit. Either way, we work to minimize downtime.

We also use what we learn from field problems to improve our designs. If we see a recurring issue with a certain component, we go back and improve it. That’s how you end up with a pellet plant equipment in Canada line that gets more reliable over time, not less.

Why This Matters for Your Project

If you’re looking at a pelletizer for sale Canada, you have options. There are plenty of companies that will sell you a machine. But a pellet plant in Canada that actually works—that runs reliably day after day, that produces consistent quality, that fits your site and your raw material—that takes more than just a machine. It takes experience. It takes attention to detail. It takes service before, during, and after the installation.

We’ve been doing this for 25 years. We’ve built plants in Canada, the US, Europe, Asia, and beyond. We’ve worked with sawdust, wood chips, shavings, slabs, logging slash, and plenty of materials that aren’t wood at all. Every project is different. But the approach is the same: figure out what the customer actually needs, then build a system that delivers it.

If you’re thinking about starting a pellet production line in Canada project—whether you’re in British Columbia, Alberta, Ontario, or Quebec—we’d like to talk. Tell us about your raw material, your site, and your goals. We’ll put together a proposal that reflects 25 years of experience, not just a price list.