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How to Choose cement feeder?

Author: Harry

Jun. 24, 2024

38 0 0

Choosing a Feeder

To select a feeder that reliably dispenses your bulk solid material at a rate your process requires, you need to understand your material and how it flows. After giving some background on material flow properties, this article describes common feeders, their major pros and cons, and how to match a feeder to your material&#;s flow behavior.

The company is the world’s best cement feeder supplier. We are your one-stop shop for all needs. Our staff are highly-specialized and will help you find the product you need.

Are your customers demanding higher-quality products? Are you trying to eliminate repetitive-motion injuries to workers and reduce your raw material costs? Then it&#;s time to consider replacing your manual feeding method with a dry bulk solids feeder that can provide more accurate feeding, eliminate manual handling and feeding tasks, and allow you to receive your raw materials in bulk, reducing their cost.

With the variety of bulk solids feeders available today, choosing the one best suited to your application will take some serious research. You need to begin by identifying your material&#;s flow characteristics. Why? Not all feeders are suited to handling all materials. Whether you conduct your own material tests or have an independent lab or your feeder supplier&#;s lab do them, the more you know about your material and how it flows, the easier it will be to narrow your feeder choices.

Your material will probably fit into one of these common categories based on the material&#;s flow properties and other characteristics:

Free flowing: A free-flowing material, like plastic pellets, flows easily by gravity without help from flow aids or specially designed equipment.


Friable: A friable material, such as wax beads, pasta products, or flake adhesives, has particles that are easily broken, so it requires gentle handling to avoid reducing the particular shape, or causing the material to flow at an inconsistent rate.

Adhesive: An adhesive material sticks to everything, making it one of most challenging materials to feed; a good example is color pigments, which are notorious for adhering to all types of surfaces.

Cohesive: A cohesive material typically has a high angle of repose and tends to pack or clump like a snowball rather than flow easily. Examples include very fine powders and powders containing fat (like a cake mix) or moisture.

Fibrous: A fibrous material, such as glass fiber, carbon fibre, wood flour, cellulose or biomass fiber, contains long particles that tend to interlock and form masses that slow or stop flow.

Fibrous materials are some of the most challenging to work with. There is a wide variety of fibrous materials, cellulose, fiberglass, carpet fibers, wood flour, husks and many more. The strand length will be an important consideration, as well as density and moisture content. Fibrous materials with short strands will be easier to work with, and long strands will be more difficult. Typical rat hole occurred during feed process below.


Aeratable: An aeratable (or floodable) material, such as talc, glass microspheres, flour, or phenolic resin, typically has a low angle of repose and behaves like a fluid when aerated. This can cause it to flood in an uncontrolled flow from an equipment discharge. Beside flowing like water when aerated, these materials can also create dangerous dust clouds, which required an explosion proofed design.

Hygroscopic: A hydroscopic material, such as sugar, salt, or cellulose fibers, readily wicks up moisture that can cause it to clump. Leaving this material in equipment overnight can cause it to harden into a rock-hard lump by morning.

Pressure sensitive: A pressure-sensitive material, such as wax beads, is prone to packing, especially under a large head load.

Meltable at low temperatures: A material with a low melting temperature tends to break down, melt, or caramelize when subjected to excess friction or energy.

Once you know which of these categories your material fits into, you&#;re ready to look at what feeders are available and how your material&#;s flow behavior will affect your feeder choice.

Common bulk solids feeder

The following information describes the operation and major advantages and disadvantages of several common feeders. Note that all but the last feeder are volumetric feeders --- that is, they dispense a volume of material at a given rate over a certain time period. By taking the desired feedrate (typically in pounds per hour) and dividing it by the material&#;s bulk density (typically in pounds per cubic food), you can calculate what volumetric throughput --- that is, what volume of material per unit time (in cubic feet per hour) --- the feeder must dispense. Once you&#;ve selected a feeder type, this information will help you determine the feeder&#;s size.


The volumetric feeders described here can also be controlled gravimetrically so they feed material at the desired rate by weight rather than volume. Gravimetric feeder control is well-suited for a material with a variable bulk density or an application requiring very high feeding accuracy.

Vibratory feeder:

A vibratory feeder is equipped with a vibratory discharge tube (or tray), Material flows into the tube and is carried gently forward by the tube&#;s vibratory action. Adjusting the tube&#;s vibration amplitude and frequency controls the volumetric throughput, which is calculated by multiplying the particle flow velocity by the cross-sectional area of the material bed in the tube.

Main advantages:

  • The vibratory feeder can handle very low and very high feedrates.
  • It produces a uniform material flow that provides gentle handling.
  • The feeder has a relatively low installation cost because the feeder&#;s low voltage requirements involve less wiring and electrical work at installation.
  • The feeder has virtually no moving parts, minimizing its maintenance requirements.
  • It has low power consumption.

Main disadvantages:

  • The feeder&#;s vibrating action can generate dust with some materials.
  • The vibrating action can segregate material blends.
  • The feeder doesn&#;t provide positive material extraction (that is, a means for pulling the material out of the feeder&#;s hopper).
  • Adhesive materials and fines can build up on the feeder tube (or tray), restricting material flow and requiring cleanout to remove the buildup.
  • The feeder doesn&#;t provide a linear feedrate (that is, it doesn&#;t achieve the same repeatability throughout its feedrate range), unlike the other feeders described in this article.

Single-screw feeder:

A single-screw feeder, a feed screw (or helix) mounted below a rigid carbon steel or stainless steel hopper and rotating inside a discharge tube (or nozzle) provides continuous material flow. The feeder&#;s volumetric throughput is calculated by multiplying the volume of material held in one feed screw flight (at a 100 percent fill level) by the screw&#;s rotation speed (in revolutions per minute).

Main advantages:

  • Changing the feed screw discharge tube configuration allows the feeder to handle a wide range of materials and feedrates.
  • The feeder provides positive material extraction, pulling material out of the feeder hopper and into the screw.
  • The feeder&#;s infeed-to-discharge distance (that is, the feed screw length) can be customized for the installation by using an appropriately sized feed screw and discharge tube.
  • Depending on the model, the feeder can be quickly cleaned or serviced by disassembling it from the non-process side, without having to take the feeder off the production line.

Main disadvantages:

  • Adhesive materials and fines can build up inside the feeder, restricting flow.
  • The screw feeder&#;s moving parts can wear, especially when handling abrasive materials, increasing required maintenance.
  • The feeder typically consumes more power than a vibratory feeder, giving it a higher operating cost.

Externally agitated screw feeder with flexible hopper:

This feeder is a specialized version of a single-screw feeder, with a hopper made from a flexible material (typically plasticized polyvinyl chloride or EPDM). Agitating steel paddle (or other devices) are mounted to rest against the hopper&#;s exterior. As the feeder operates, the paddles gently massage the hopper sides to facilitate flow from the hopper and complete filling of the screw flights.

Main advantages:

  • The feeder provides positive material extraction.
  • The agitation promotes first-in first-out flow to minimize blend segregation or degradation of friable materials.
  • The agitation can condition an aeratable material to a uniform bulk density so it can completely fill the screw flights.
  • The agitation promotes smooth flow by breaking material bridges over the feed screw and preventing ratholes.
  • The external paddles don&#;t contact the material in the hopper, preventing buildup and contamination problems.
  • The feeder can be equipped with dual drive (with one motor for the feed screw and another for the agitating paddles) that allows the operation of each to be adjusted for handling various materials.

Above you see a single screw feeder with external agitation feeding a cohesive product, China clay - Kaolin

Main disadvantages:

  • It can&#;t be used with high-temperature (212°F or higher) materials, which can melt the hopper walls.
  • This feeder can&#;t be used with fibrous material or some cohesive materials that tend heavily to pack.
  • If the feeder is equipped with a single motor, increasing the feed screw rotation speed also increases the paddles&#; agitation frequency, reducing the feeder&#;s ability to handle some materials.
  • When equipped with a dual drive, the two motors will increase the feeder&#;s initial and operating costs. However, the dual drive&#;s flexibility for handling various applications can make this feeder less costly to operate than other feeders in the same applications.

Internally agitated screw feeder:

Another type of single-screw feeder has a hopper equipped with an internal agitator that rotates vertically or horizontally, to promote material flow into the screw flights.

Main advantages:

  • The feeder&#;s rotating agitator eliminates bridging and ratholing of cohesive materials.
  • The feeder promotes the flow of fibrous materials.
  • The feeder hopper can be carbon steel or stainless steel, allowing the feeder to handle materials incompatible with the vinyl hopper wall of an externally agitated screw feeder.

Below an example of a internally agitated feeder with a flat bottom feeding fibrous wood flour.

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Main disadvantages:

  • The internal agitator directly contacts the material, potentially leading to buildup and contamination problems.
  • The feeder isn&#;t recommended for handling adhesive materials because they can build up on the internal agitator.
  • The feeder may not prevent blend segregation or degradation of friable materials.
  • It requires installation in a location with enough headroom to allow the internal agitator to be removed for cleaning and service.

Twin-screw feeder:

This feeder has a pair of feed screws rotating side-by-side inside a discharge tube. A gear-reduction doubler splits the drive motor&#;s rotational energy between the screws.

Main advantages:

  • The feeder provides positive material extraction.
  • The feed screws intermesh as they rotate which typically makes the feeder self-cleaning and reduces material buildup.
  • The two screws tend to produce smaller flow pulses than a single screw does, leading to better second-to-second feeding accuracy

Main disadvantages:

  • The twin-screw feeder requires a higher initial investment and more maintenance than screw feeders with one screw, increasing its costs.
  • The feeder isn&#;t suitable for feeding pellets, which can become pinched between the screws.
  • If the feed screws become caked with material, they&#;re difficult to remove for cleaning.
  • The screws and discharge tube are available in limited lengths, limiting the ability to customize the twin-screw feeder&#;s infeed-to-discharge distance.

Weighbelt feeder:

A weighbelt feeder provides a continuous flow of material on a moving conveyor belt with a weighing section, making it a gravimetric rather than a volumetric feeder. The material passes under a shear gate, giving the material a consistent, uniform profile as it travels over the weighed section. While not a volumetric feeder, its volumetric throughput can be calculated by multiplying the material bed&#;s cross-sectional area by the belt speed.

Main advantages:

  • The weighbelt feeder provides positive material extraction from the hopper.
  • It provides gentle handling for friable materials.
  • The feeder is available in a variety of belt widths to feed at higher rates and handle larger particle sizes than other feeders.
  • The feeder fits more easily in low-headroom locations than other feeders.
  • Like a belt conveyor, the feeder has relatively simple construction compared with vibratory or screw feeders, making it easier to clean and maintain.

Main disadvantages:

  • If the feeder is misapplied, the belt can wear and require periodic replacement, especially when handling an abrasive material, and the belt&#;s wear particles can contaminate the material.
  • Cohesive and adhesive materials and fines tend to build up on the belt, creating problems that can affect the feedrate and belt tracking.
  • Depending on the belt&#;s length, the feeder typically isn&#;t suitable for an aeratable material, because the material can fail to form a stable bed on the belt.
  • The feeder generates dust unless the feeder is enclosed and equipped with dust collection.
  • The feeder requires more maintenance than other feeders; in addition to periodic belt replacement in some applications, the feeder requires regular maintenance to prevent belt slippage and tracking problems.

Choosing a feeder for your material

For each of the material types described previously, find information here about which feeders are best suited to it, along with some practical feeding tips.

Free-flowing material: A free-flowing material doesn&#;t require the positive extraction provided by a screw feeder, making the energy-efficient vibratory feeder a good choice for handling it.

Friable material: The gentle handling provided by vibratory and weighbelt feeders makes either ideal for feeding a friable material.

Adhesive material: Any of the screw feeders discussed here, except for the internally agitated screw feeder, is well-suited for handling an adhesive material because of the feeder&#;s positive material extraction (An internally agitated screw feeder isn&#;t recommended for an adhesive material because the particles can quickly build on the feeder&#;s agitator.) Periodically clean the feed screw and discharge tube to prevent adhesive material from building up on the components. You can also select feeder components with Teflon coatings or more polished contact surfaces and use a self-cleaning system inside the discharge tube to prevent buildup.

Cohesive material: Feeding this material typically requires the positive extraction provided by a screw feeder, but the feeder must also be equipped with some type of flow aid to break up material clumps. Good choices include externally agitated and internally agitated screw feeders and other screw feeders that have hoppers equipped with air sweeps or air pads.

Fibrous material: An internally agitated screw feeder is well-suited to handling a fibrous material because the agitating action inside the feeder hopper pushes the material into the screw feeder.

Aeratable material: A screw feeder, and in particular an externally agitated screw feeder, is a sound choice for preventing an aeratable material from flooding out of the feed screw during feeding. Selecting a feed screw with a center rod rather than a standard open-flight design can also prevent this problem. To avoid aerating the material during refill, refill the feed hopper frequently with a small amount of material rather than less often with a large amount.


Hygroscopic material: Which feeder is best for a hygroscopic material depends on how hygroscopic it is and how well the application environment is controlled. Any of the feeders discussed in this article can handle a less hygroscopic material, such as phenolic resin, in a humidity-controlled environment, even mildly hygroscopic materials can wick up enough moisture to prevent them from feeding. In an enclosed feeder, a hygroscopic material can also be blanketed with clean, dry air or nitrogen to keep moisture out and promote uniform flow.

Pressure-sensitive material: Any of the feeders described in this article is suited to handling a pressure-sensitive material, as long as the feeder doesn&#;t have a large-volume hopper extension, which can cause the material to pack. If the feeder must have such a hopper extension, use frequent smaller refills to help prevent packing problems. When using a vibratory feeder or an externally agitated screw feeder with this material, avoid high-frequency vibration or agitation to prevent packing problems.

Material that melts at low temperatures: This material can be fed by any screw feeder, but a screw feeder with a large-diameter feed screw rotating at a low speed is better suited to it than one with a small-diameter screw at high speed. However, the larger the feed screw and the slower the screw speed, the less feedrate accuracy the feeder can achieve.

Author:

Manfred Bruckner Schenck Process Europe GmbH

Bulk material feeder types and applications

Stockpile activators are used to avoid ratholing, which is where a steep-walled hole develops in the material bed at the underground reclaim point, with the surrounding material remaining stagnant. The vibratory nature of stockpile activators also prevents material bridging over the reclaim point opening. A longitudinal stockpile may have multiple stockpile activators located along the length of the underground (tunnel) reclaim conveyor. Circular stockpiles may have a single unit at the center. 

Below the hopper discharge, either an angled chute and clam-shell gate combination or a vibratory feeder can be used to control the material flow from the hopper and prevent material from flooding onto the belt conveyor below. 

Bin activators. Bin activators (also known as draw-down hoppers) are similar in principle to stockpile activators. They are connected to the discharge point of a bin and are hung on suspension arms to allow the bin activator to move relative to the bin. A motor and vibrator are attached to the bin activator ring, which typically includes cross bracing inside the ring with an inverted cone to moderate material flow through the opening. The space between the bin activator ring and the bin is sealed with rubber that accommodates the vibrating motion. Bin activators are usually used with materials that have small to medium particle sizes. 

Pushing or dragging

Screw feeders. Screw feeders consist of a round-bottomed enclosed casing, often with a top-mounted inlet at one end and a bottom-mounted outlet at the opposite end. In some cases, a screw feeder essentially fits along the bottom slot of a hopper, with the material in the hopper sitting on top of the screw. This is known as a live-bottom hopper. Live-bottom arrangements can include multiple screws in parallel, providing a greater footprint area to draw down material from the hopper. 

For a single-screw feeder, the screw is within the casing, and the pitch of the screw flights can be graduated from the tail at the inlet end to the head at the outlet end to avoid compressing the material within the flights along the length of the screw. The pitch on the screws increases closer to the head end, allowing for efficient material flow. 

Some screw feeders incorporate tapered screw blades, with the blades getting larger along the length, while others have tapered shafts to control the cross-sectional area of material being pushed at each point along its length. The screw shaft is kept in position with hanger bearings mounted at regular intervals from the top of the casing or standing bearings mounted from the bottom of the casing. 

In all cases, the screw is driven by a drive unit mounted at one end of the screw feeder and connected directly to the screw shaft. 

For regular screw feeders, material falls through the inlet via gravity. Material then collects on the bottom of the screw feeder casing and is pushed forward by the screw&#;s flights as the screw rotates. For live-bottom applications, the material sits on top of the screw (or screws) and is drawn down into the screw flights and pushed forward to the discharge. 

Because screw feeders are fully enclosed, they are a good mechanism for dust containment, assuming that all flanged connections are adequately sealed. 

Rotary plough feeders. A rotary plough feeder consists of plough blades, a plough drive unit, a long travel drive, and a mounting frame with wheels. Rotary plough feeders are used underneath hoppers with a longitudinal slot along the wall. The leading edge of the plough blades fit into the slot, and material falls onto the blades as they rotate in plan view and drag material out of the hopper through the slot. Material is then discharged directly onto a belt conveyor that runs parallel to the hopper slot. The mounting frame of the plough feeder straddles the belt conveyor and sits on rails that run down either side of the conveyor. Due to the arrangement, the conveyor is located within a tunnel or longitudinal chamber. 

The plough feeder&#;s main application is to reclaim material onto conveyors. This type of feeder is most often implemented within the coal industry and can be used in medium to heavy-duty applications. 

Drag chain feeders. Drag chain feeders are fully enclosed within a casing. At each end of the feeder is a sprocket (analogous to the pulley in a belt feeder) that drives a longitudinal chain with plates mounted to it at regular intervals. The material inlet is located on the top near the tail end of the casing, and the material outlet is located on the underside at the head end of the casing. As the chain rotates, the plates on the lower strand of the chain drag material through the casing from the inlet end to the outlet. 

Drag chain feeders can have circular, square or rectangular cross sections depending on the application requirements. The casing must be shaped accordingly to minimize cross-sectional voids along the length of the feeder and maximize material dragging. 

Like screw feeders, drag chain feeders are fully enclosed, making them good for dust containment. Accordingly, they are used for lower throughput capacities and smaller (sometimes powdery) particle sizes. Drag chain feeders are most commonly applied in furnace feed systems. 

Reclaim feeders. A reclaim feeder (Figure 4) is a specialized drag chain feeder used to reclaim material from stockpiles and deliver the material to conveyors. Reclaim feeders consist of a drag chain within a housing and connected to a drive unit shaft via sprockets. The tail section of the reclaim feeder is horizontal and is placed at grade. The reclaim feeder then inclines and elevates the material high enough to be easily discharged onto a belt conveyor. Between the feeder&#;s tail and inclined sections is a wing wall that prevents spillage that can occur from the pushing of material by dozers. The wing wall includes a profile plate to regulate the cross section of the material passing through to the feeder&#;s incline section. The inclined section has side walls that contain material and prevent spillage.

Contact us to discuss your requirements of horizontal cement silos. Our experienced sales team can help you identify the options that best suit your needs.

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