Choosing the Most Effective Pumps for Slurry Handling

When working with slurry, choosing the right pump is crucial. A slurry is a mixture of solids and liquids, often thick and heavy. It can be found in many industries, including mining, construction, and wastewater treatment. The right pump for slurry can make a big difference in how efficiently you can move and manage this mixture. In this article, we will explore the different types of pump for slurry handling, their features, and how to choose the best one for your needs.

What is a Slurry?

Before we discuss the types of pumps, let’s define slurry pumps. A slurry is a mixture of solid particles suspended in a liquid. It can be thick and challenging to move. Common examples of slurry include cement, mud, and mining tailings. Because of its unique properties, handling slurry requires special equipment.

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Types of Pumps for Slurry Handling

Several types of pumps are available for moving slurry. Each type has its advantages and disadvantages. Here are some of the most common types of pumps for slurry handling:

1. Centrifugal Pumps: These are the most widely used pumps for slurry. A centrifugal pump uses a rotating impeller to move the liquid. The impeller spins, creating a force that pushes the slurry through the pump. Centrifugal pumps are practical for low-viscosity slurries and can quickly handle large volumes of liquid. However, they may need help with very thick or abrasive slurries.
2. Positive Displacement pumps: Displacement pumps work by trapping a fixed amount of slurry and forcing it through the pump. They are great for high-viscosity slurries and can handle thick mixtures well. However, they generally operate at a slower speed compared to centrifugal pumps.
3. Industrial Slurry Pumps: These are specially designed for heavy-duty applications. An industrial slurry pump can handle abrasive materials and large solid particles. They are often used in mining and construction industries where the slurry is demanding and requires robust equipment.
4. Submersible Pumps: These pumps are designed to operate underwater. They are often used in applications with slurry at the bottom of a tank or pit. Submersible pumps can be very effective for moving slurry in confined spaces.

Choosing the Right Slurry Pumps

When selecting a pump for slurry, there are several factors to consider. Here are some key points to help you make the right choice:

Type of Slurry

The first step is to understand the slurry you will be handling. Is it thick or thin? Does it contain large solid particles? Different pumps are better suited for specific types of slurry. For example, a positive displacement pump may be more effective if you are dealing with a thick slurry. If the slurry is less dense, a centrifugal pump for slurry could be the better option.

Pump Capacity

Next, consider the pump’s capacity. How much slurry do you need to move? Slurry Pumps come in various sizes and capacities. Choosing a pump that can handle the required flow rate is essential. If you need to move large volumes of slurry quickly, a centrifugal pump might be the best choice.

Material Compatibility

The materials used in the pump must be compatible with the slurry. If the slurry contains abrasive materials, you need a pump made from durable materials that can withstand wear and tear. Industrial pumps are often built with hard materials to resist abrasion.

Operating Conditions

Consider the environment where the pump will be used. Will it be indoors or outdoors? Is it exposed to extreme temperatures or corrosive substances? The pump must suit operating conditions to ensure optimal performance and longevity.

Maintenance Requirements

Different pumps have different maintenance needs. Some pumps may require regular servicing, while others are designed for low maintenance. Choosing a pump that fits your maintenance capabilities and schedule is essential.

What is a Centrifugal Pump for Slurry?

A centrifugal pump for slurry operates by using a rotating impeller to create a centrifugal force. This force moves the slurry through the pump, allowing it to be transported efficiently. Unlike standard centrifugal pumps, slurry pumps are built to withstand the abrasive nature of solid particles within the mixture. They are often constructed with wear-resistant materials to prolong their lifespan and maintain efficiency.

Key Features

1. Robust Construction: these pumps are designed with heavy-duty components that can handle the wear and tear caused by abrasive materials. This includes reinforced casings and impellers made from durable alloys or rubber linings.
2. High Capacity: These pumps can manage large volumes of slurry, making them suitable for high-demand applications. They can move thick mixtures quickly and efficiently.
3. Versatility: Centrifugal pumps can be used in various applications, such as transporting tailings in mining, mixing concrete in construction, and handling sludge in wastewater treatment.

Applications

Centrifugal pumps for slurry are widely used in industries that require the movement of heavy, viscous fluids. In mining, they transport ore and tailings, while in construction, they help in pouring concrete and managing site drainage. Their ability to handle high-density materials makes them invaluable in these sectors.

Advantages of Using the Right Pump

Choosing the right pump for handling has several advantages. Here are a few benefits:

• Efficiency: The right pump can move slurry more efficiently, reducing energy costs and time spent on the job.
• Reduced Wear and Tear: A pump designed for the specific type of slurry will experience less wear and tear, leading to lower maintenance costs and longer equipment life.
• Improved Safety: Using the correct pump can help prevent spills and accidents, making the work environment safer for everyone involved.
• Higher Productivity: With the right pump, you can handle slurry more effectively, leading to increased productivity and better overall results.

Typical Applications for Slurry Pumps

Slurry pumps are used in various industries. Here are some typical applications:

1. Mining: Pumps transport tailings and other mixtures in the mining industry. The pumps effectively handle abrasive materials and large solid particles.
2. Construction: Pumps are often used to move cement and other thick mixtures. They help in the efficient pouring of concrete and other materials.
3. Wastewater Treatment: In wastewater treatment plants, pumps move sludge and other mixtures through the treatment process. They are essential for maintaining the flow of materials in the system.
4. Agriculture: Pumps are used to handle manure and other organic materials. They also help manage waste and fertilizers efficiently.

Tips for Maintaining Industrial Slurry Pump

Proper maintenance is essential for the longevity and efficiency of pumps. Here are some tips to keep your pump in good condition:

1. Regular Inspections: Check the pump regularly for signs of wear and tear. Look for leaks, unusual noises, or vibrations.
2. Clean the Pump: Keep the pump clean to prevent clogging. Remove any debris or buildup that may affect performance.
3. Lubricate Moving Parts: Ensure all moving parts are properly lubricated to reduce friction and wear.
4. Monitor Performance: Monitor the pump’s performance. If you notice a drop in efficiency, it may be time for maintenance or repairs.
5. Follow Manufacturer Guidelines: Always follow the manufacturer’s recommendations for maintenance and operation to ensure optimal performance.

Conclusion

Choosing the right pump for slurry handling is critical for efficient and effective operations. You can make an informed decision by understanding the different types of pumps available and considering factors such as slurry type, pump capacity, material compatibility, operating conditions, and maintenance requirements.

Nnamdi Nwaokocha offers practical advice on pump selection

PUMPS are the backbone of the process industry. In a process plant, it is necessary to move material from one point to another. In keeping with the laws of thermodynamics, fluids move from an area of high pressure to low, and depending on the plant layout often require the assistance of a pump to achieve this. With many different pump types available, selecting the right pump can be tricky, especially when slurries are involved.

This article will discuss some of the variables to consider when characterising a slurry and selecting a suitable pump for transporting those slurries in a plant. This is not definitive and is by no means a complete review of handling slurries by pumping but is meant to provide some useful information and a good starting point of what to consider.

Summary

Pumping of slurries can often lead to blockages or equipment failure. The job of the designer is to assess all the factors of each situation, including client and existing site preferences to design a system and select a pump which is robust enough to minimise blockages and makes maintenance for operators as easy as capital would permit whilst providing a safe system of work.

Slurry type

What is a slurry? Typically, the term slurry is used to refer to a mixture of a liquid and a solid or combination of solids. The liquid is often referred to as the carrier fluid and in most cases is water, although it can be anything from an acid solution (eg nitric acid) to a hydrocarbon (eg diesel).

Producing a slurry or maintaining solid suspension in static conditions is outside the scope of this article.

Slurries can broadly be broken down into two types: settling, and non-settling slurries. This characterisation is based on the nature of the solid(s). Non-settling slurries contain solids made up of fine particles, which largely remain in suspension when the applied mixing energy ceases. Settling slurries, as the name suggests, contain solids whose particles settle out when the applied mixing energy ceases. From a designer’s perspective, it is important to know the type of slurry. For example, non-settling slurries can be transported around under laminar flow conditions, whereas turbulent flow conditions are required for settling slurries, particularly in horizontal sections.

A useful rule of thumb provided in Sinnot and Towler’s Chemical Engineering Design states that solids with particles of less than 200 microns (0.2 mm) will usually be expected to produce non-settling slurries. Larger particle sizes will produce settling slurries.1

Before selecting the right pump, the first step is to determine the pressure drop requirements using the system characteristics. The parameters required are:

The following equations2 are useful in determining the slurry’s density:

For settling slurries, the velocity in the pipework is the key design criteria.

Perry’s Chemical Engineers’ Handbook

Figure 1, an extract from Perry’s Chemical Engineers’ Handbook, depicts the relationship between the pressure drop and the slurry’s velocity compared to a pure liquid in horizontal pipework. The important point to note is that the horizontal pipe velocity should be above the point labelled Vm2 (minimum transport velocity). This is the point at which the solids are fully suspended. This is determined using the Durand equation3. 

where:

Once the minimum transport velocity is calculated, it is common to add a safety factor, but care is needed. If the velocity is too high, the required pressure drop and the subsequent work required by the pump can increase significantly. For vertical flow, a good  starting velocity can be taken as twice the solid’s settling velocity. The main aim is to stop the solids from dropping out. Velocities in the range of 1-3 m/s is  a useful rule of thumb.3

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The pressure drop for settling slurries can now be determined at the calculated velocity assuming pseudo-homogeneous behaviour, using the slurry’s density and the carrier fluid’s viscosity in established pressure drop calculation and applying a correction factor. A correction factor of 25% is suggested in Perry’s Chemical Engineers’ Handbook3.

Note that the above is for solids heavier than the carrier fluid. Depending on the solid particle size, at particular concentrations the particles begin to interact with each other and can start to affect the slurry’s viscosity. This is discussed further with calculations provided in the Processing of Solid-Liquid Suspensions, Chapter 112. Appendix 3, Warman Slurry Pumping Handbook4, also has useful calculations and correlations for water-based slurries.

Perry’s Chemical Engineers’ Handbook

For non-settling slurries, the resultant slurry typically displays non-Newtonian behaviour, and its rheology and behaviour must be determined empirically to ascertain the work required by the pump. The pressure drop for these can then be calculated using established pressure drop calculations depending on the slurry viscosity and density calculated.

Other things to consider before moving onto pump selection are:

• slip conditions – when the solid and carrier velocities differ significantly;
• pipe size – ensure the pipe ID is considerably bigger than maximum particle size (6-10x is recommended2);
• piping design (using recirculation loops to ensure the slurry is constantly moving; using falls, so the  slurry drains to a safe point; using long radius bends; installing rodding or flushing points; minimising bends; minimising dead legs; minimising suction pipework);
• static head requirements; and
• available NPSH.

The solid particle will play a crucial part in selecting the material of the wetted parts. The following, amongst other things, should be considered:

• are the solids hard or soft? ie are they abrasive?
• will pumping the slurry cause erosion?
• are the solids corrosive? This applies to the carrier fluid.

Pump types

As with many pump duties, both rotary and positive-displacement pumps can be utilised. The following are some of the aspects to consider when selecting the type of pump for your slurry. However, always check with specialist pump suppliers before making a final decision.

Centrifugal pumps

The most common pumps generally in use are centrifugal pumps. When specifying this type of pump, as a minimum, the following must be considered:

• Impeller type – A recessed impeller type can be used, the design minimises contact between the particles and the impeller thereby minimising wear on the impeller whilst being gentle on the particles. Open impeller types can be used, as they are generally easier to clean and maintain. Closed impellers are often regarded as having the best efficiency but can be difficult to clean. The thickness should have suitable wear allowance. You should also consider any impact caused by the required impeller speed.
• Casing type – Metal casings can be used. These may be lined with rubber for added protection or as a sacrificial wear part. Split casings can also be considered, but these can be expensive. The thickness should have suitable wear allowance.
• Clearances – Slurry centrifugal pumps should have larger clearances than pure liquid pumps, to allow solids to pass through but also to reduce the velocity within the pump, thereby minimising wear.

These are just some of the things to consider when selecting a centrifugal pump for a slurry duty. In direct liaison with a pump vendor, the designer must choose the best options for their system. They should also consider any impact on the shaft and seals, and ensure there will be no issues with cavitation.

Centrifugal pumps are differential head devices and therefore, the head generated is based on properties of the fluid.

Warman Slurry Pumping Handbook

Often, the operating curve and efficiency curve provided by pump vendors are that of water, so a way of translating those figures is often needed. An example is shown in Figure 34. It also includes a ratio for the driver efficiency which would also assist in confirming the pump motor.

Note that the curve is only for slurries whose carrier fluid is water. Moreover, it is for Warman pumps. For similar correlations and fluids other than water, speak to your pump vendor.

Positive displacement pumps

There are various types of positive displacement pumps which may be utilised in pumping slurries: air-operated diaphragm pumps, peristaltic, rotary lobe, progressive cavity pumps, and piston diaphragm pumps to name a few. Assessing all of these to the same degree as the centrifugal pump above will be a significant undertaking and is outside the scope of this article. Instead, I’ve summarised different pump types used in my experience and highlighted specific things to consider in relation to handling slurries.

Positive displacement (PD) pumps are generally useful for fluids, which demonstrate pseudo-plastic behaviour. The pumps are better equipped to overcome that initial resistance to  flow. They generally run at lower speeds compared to centrifugal pumps and are therefore consequently gentler on the solid particles. However, some PD pumps are known to generate acceleration losses, which must be accounted for.

Air-driven diaphragm pumps

Generally, I have found air-driven diaphragm pumps to be suitable for handling slurries. However, as with centrifugal pumps, abrasion and erosion can be an issue, particularly with the balls and seats that form part of the check valve assembly. If the right material is not selected, the balls can be eroded to a point where they no longer seal properly, causing the pump to not operate efficiently. The same thoughts can be applied to piston diaphragm pumps.

Things to consider (specifically related to slurry handling) include material of check valve assembly; material of diaphragm; and clearances (the maximum particle size the pump can handle).

Peristaltic pumps

Peristaltic pumps are alternatives to air-driven diaphragm pumps. Unlike the diaphragm pumps, there are no balls or check valves to maintain. To put it simply, the only things which require maintenance are the motor and the tube. The main advantage of this pump type is the capability to handle slurries up to 80% w/w solids (this is the highest value I’ve seen claimed, and should be confirmed with your pump vendor). A limiting factor in its selection is the maximum discharge pressure, and this is limited ultimately by the tube properties. Things to consider include tube material (hence tube life), and maximum discharge pressure.

Gear, lobe and ECP pumps

In these pump types, fluid is moved in the spaces between the teeth of the gear pump, lobes or pistons. They typically are specified for slurries with soft particles. ECP pumps are known  for dealing well with slurries that contain solids which settle readily, as they can be scooped up once flow is resumed. The clearances are usually quite tight in these pump types and any slurries which contain abrasive solids would cause excessive wear on these pumps5.

Things to consider include slurry type, and solid characteristics.

Progressive cavity pumps

Used extensively in the wastewater and process industries, this pump is well known for handling slurries. To improve wear resistance whilst pumping slurries, the rotor may be coated. The more abrasive the solids in the slurry the better it may be to operate the pump more slowly, ie select a larger pump and operate at a slower speed. Additionally however, if the pump is operated slower then solids may fall out of suspension and cause blockages within the pump. Be careful when looking to handle larger diameter solids. A limit of 45 mm is stated in Jones’ Pump Station Design.7

Things to consider include solid characteristics (size and abrasiveness), slurry type (do they settle easily?) and seal arrangement.

Conclusion

Selecting a suitable pump for a slurry application can be a tricky business. There are many variables to consider, some of which have been mentioned in this article. The overriding message  though is to ensure that the solids remain in suspension and to minimise wear and blockages. The above is provided for discussion and general guidance purposes only. For specific cases, you should gather as much information as possible on the carrier fluid and solids, and discuss options with a relevant pump vendor.

References

1. Sinnot, R and Towler, G, Chemical Engineering Design, Fifth Edition, Elsevier, .

2. Processing of Solid-Liquid Suspension, ed Ayazi Shamlou, P,   Chapter 11 by Shook, CA, Chapter 12 Etchells, AW, Butterworth-Heinemann, .

3. Green, DW and Perry, RH, Perry’s Chemical Engineers’ Handbook, Chapter 6, 8th Edition, McGraw-Hill, .

4. Warman Slurry Pumping Handbook, Warman International, Feb .

5. https://bit.ly/2Ud76ls

6. Coulson, JM, Richardson, JF, Backhurst, JR, Harker, JH, Coulson and Richardson’s Chemical Engineering Volume 1 - Fluid Flow, Heat Transfer and Mass Transfer, 6th Edition, Elsevier, .

7. Jones, GM, Pumping Station Design, revised 3rd edition), Elsevier, .