what is the difference between tyrash mud pump factory

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Mud Pumps come in both electric and gas / diesel engine drive along with air motors. Most of these pumps for mud, trash and sludge or other high solids content liquid dewatering, honey wagon and pumper trucks. Slurry and mud pumps are often diaphragm type pumps but also include centrifugal trash and submersible non-clog styles.

WARNING: Do not use in explosive atmosphere or for pumping volatile flammable liquids. Do not throttle or restrict the discharge. Recommend short lengths of discharge hose since a diaphragm mud pump is a positive displacement type and they are not built with relief valves.

Some of you may have heard this term and some may not: trash pumps. These pumps are designed for dewatering applications and are portable. These kind of pumps have the capability of moving water with solids in it such as twigs, sludge, sand, leaves and mud. Most trash pumps are portable versions of heavy duty centrifugal pumps.

The impeller veins are deeper and the discharge openings are much larger than similar pumps that are not designed to be trash pumps. Consequently, these pumps are able to move fluids with solids that would clog up standard centrifugal pumps. Not only can they move fluids containing too many solids for other pumps, they can also move them at a high rate of speed.

While many pumps grind up the solid materials that enter the pump, trash pumps do not. In addition to the deep impeller veins and large discharge openings, these pumps feature a full pump housing. These pumps can be made from a variety of materials, including: cast iron, stainless steel, steel and aluminum. Roll cages are also common standard equipment on most trash pumps.

There’s another variation called a semi trash pump, which does not have as large of a discharge opening as a trash pump. Due to the smaller opening, they cannot handle larger solids, nor can they handle a high density of solids.

Some manufacturers do not always differentiate between trash pumps and semi trash pumps, so it is important to work with a company that provides comprehensive customer service.

Trash pumps are designed for a wide range of wastewater and solids handling applications. With available impeller options and stainless steel self priming centrifugal models, trash pumps are typically made to pump wastewater with some solids. Stringy material is not a trah pump specialty however. From industrial treatment plants, municipal solids handling, settling ponds, remote sewage lift stations, on-site treatment, Trash Flow’s are known for years of consistent and reliable pumping.

Many pumps are available in the marketplace today for many different applications, including: sewer bypass, wellpoint dewatering, dewatering excavations, and many others. Determining the best pump to use on a particular application can be a challenging enterprise. Choosing the right pump can mean a profitable job, while on the other hand, choosing the wrong pump can spell trouble and result in costly downtime. Listed below are the some of the features to look for in a quality trash pump.

Priming and Repriming Capability – Many factors can contribute in causing a pump to lose its prime. One factor is the water level dropping in, causing the suction hose and strainer to be exposed and allow air to enter the hose. This causes many pumps to lose prime and stop pumping. Holes, tears, or improper installation of the suction hose can also contribute to the loss of prime. If the pump is not able to regain prime, the project can become unsafe, resulting in damage to equipment and personnel. Choosing the right pump depends upon overall application requirements and customer preference.

pump casing, which when filled with water before operation, will prime and reprime automatically without the aid of an auxiliary priming device. Wet prime pumps are capable of handling about 29-cfm of air. Some manufacturers use wet-priming pumps and install a priming device, such as a vacuum pump or a compressor pump to add additional air handling capability for quicker priming and repriming times.

Straight, end-suction centrifugal pumps are reliant on the use of an auxiliary priming device, such as a vacuum pump, compressor pump, or hand device to achieve and maintain prime because they are not capable of handling air on their own. If the priming system should fail, pumping cannot continue until the priming system is repaired.

Dry-priming pumps employ a wet prime, self-priming centrifugal trash pump, or an end-suction centrifugal pump. Dry-priming means that these pumps do not require the pump casing to be filled with water, as do wet-priming pumps, and rely on the air

handling capability of their automatic priming systems to remove the air from the suction line, creating a vacuum, and drawing the fluid into the pump casing. This is beneficial especially during freezing temperatures when freezing water in the volute could cause the volute to break, or having your pump far from the nearest water source, where buckets of water would have to be brought to the pump casing just to achieve prime. They are fitted with automatic priming systems such as vacuum pumps or compressor pumps, keeping the pump primed continuously. These add-on accessories are able to provide large air handling capability (especially when installed on wet-priming pumps), quicker priming times, the ability to reprime if priming water is lost, and added versatility that can truly make a difference on the job.

A vacuum-assisted priming system consists of a vacuum pump that is powered by the diesel engine; a set of wire-reinforced supply and return line hoses to provide lubricating oil to the vacuum pump; a discharge check valve to prevent air and pumping effluent from entering the pump during downtimes and; an air separator chamber with a float system to regulate the air as it enters the pump. Some vacuum pumps can provide an extra 78-cfm of air handling capability, and are an excellent addition to a wet-priming pump that has air handling capability on its own.

A compressor-assisted priming system consists of a compressor that is also powered by the diesel engine; an air separator chamber with a float system to regulate the air as it enters the pump; a discharge check valve to prevent air and pumping effluent from entering the pump during downtimes and; an air eductor, or venturi system, connected to the compressor and the air separator by a series of hoses and used to force the air to create the vacuum in the suction line. The venturi is manufactured to precise specifications and is made to only handle air.

If pumping effluent infiltrates the priming system and escapes out of the venturi, it can cause the venturi to fail and not be able to prime the pump until repaired or replaced. To replace the venturi is a major expense – so it is important to associate with a pump manufacturer who has success in keeping the pumping effluent away from the venturi, such as Thompson’s ENVIROPRIME® Priming System. Some compressor pumps can provide an extra 14-cfm of air handling capability, and are an excellent addition to a wet- priming pump that has air handling capability on its own.

Submersible pumps are submersed directly into the pumping effluent and reprime automatically when the water level covers the strainer. Sometimes, submersible pumps are attached to floatation devices, which keeps the strainer of the pump submersed, and therefore, keeps its prime.

Broad Operating Range – The flow rate into an excavation can vary from several hundreds of gallons per minute of water at the beginning stages of the job to a few gallons per minute at the later stages of the job. The right pump must be capable of handling the maximum pumping capacity to lower the groundwater table as well as operating satisfactorily at reduced flow rates to maintain the groundwater table at the desired sub-grade.

Dry Running Mechanical Seal – When the pumping effluent levels reduce, the pumping capacity will typically diminish. During these periods, the pump’s capacity can far exceed the seepage rate into the excavation causing the pump to run completely dry. Pumps are available with special seal materials such as tungsten carbide and automatic lubricating systems (grease or oil) to allow the pump to operate during long periods of dry running, operating without pumping effluent entering the pump casing, without damage.

High Suction Lift Capability – As a site is excavated below the natural groundwater table, there is the potential for a larger quantity of water to enter the excavation. Moreover, the deeper the excavation, the greater the reduction on the pump’s capacity. The right pump must be capable of pumping the required capacity at the given suction lift.

Trash Handling Capability – The water entering an excavation is often mixed with sand, rocks, sticks, etc. The right pump must be capable of passing large debris without binding or damaging the pump.

Heavy-Duty Cast Iron Construction – To ensure satisfactory life and reliability when handling trash-laden water, the pump should be constructed of heavy-duty cast iron components.

Inspection Port – Trash handling pumps are fitted with lightweight removable covers allowing easy access to the pumps interior for removal of trash, without disturbing the suction or discharge hoses.

Replaceable Wear Plate – The most expensive component of the pump by far is the pump casing. A quality trash pump incorporates a replaceable wear plate to protect the pump casing from wear and to prolong the life of the pump casing. Some wear plates are even equipped with a rubber lining to further protect the casing against abrasion.

Front Pull-Out Feature – Certain trash pumps are available with a front pull-out design. This design includes a lightweight front cover that allows access to the pump interior for removal of blockage and replacement of the internal pump components in the field without disturbing the suction or discharge hoses.

24-Hour On-Board Fuel Tank – Trash handling pumps for dewatering are required to operate continuously to keep water out of the excavation. This includes at night when the work crews have gone home. For this reason, trash-handling pumps are available with on-board fuel tanks permitting the pump to operate up to 24-house before refueling. This gives the contractor the luxury of not having to send personnel out during the night to refuel the pump.

Sound Attenuation – Sound attenuated pumps are becoming one of the strict demands of municipalities nationwide. When pumping in a highly populated area, especially when it’s required to pump into the night, sound attenuated pumps are necessary. Thompson Pump has spent years perfecting providing pumps with options that help users do their jobs easier. Thompson Pump is the only pump company with a completely removable, modular sound attenuated canopy. This allows the freedom of having the right pump for the job at hand.

Versatility & Dependability – A quality trash pump must not only have quality components, but they also must be able to be versatile enough to be used on many different applications, and dependable enough to ensure that it will perform well on those applications. Many companies depend on multi-purpose products to be able to keep costs down while being able to use that product in different applications, and increasing their revenue. The same is true with a quality trash pump. Some pump manufacturer’s trash pumps perform well on some applications, but do not perform as well on others. For example: a dry-prime trash pump with a self-priming centrifugal pump end and a high air handling capability may be used on a small wellpoint job, and also on a trash or solids application; where as an end suction centrifugal trash pump with a low air handling capability may perform well in a in a trash or solids application, but may not perform well, or at all, in a small wellpoint application.

Waste Treatment: Sewer bypasses; pumping polluted hot or corrosive wastewater containing sand, mud or solids in suspension; dosing neutralizing liquids; pumping out settled sludge

The trash pump does not grind the materials that it receives. Cast iron, aluminum, steel, and stainless steel are all possible materials used to construct trash pumps. Trash pumps use a big inlet and strong power to pick up debris while delivering maximum pressure and discharge flow. A trash pump can be powered by alternating electricity, direct current, compressed air, gas, diesel, or solar energy.

When a trash pump is operating, contaminated water is sucked in. By creating a low-pressure space inside the pump cavity, the pump sucks in the fluid. A trash pump’s impeller generates the water"s kinetic energy. Water is moved axially and radially by the impeller blades" centrifugal force. To further compress the water, the filtered water is directed into the volute casing while the debris and other solid particles are transported toward the pump’s central hub.

The speed is converted into pressure energy via the volute case. This power aids in processing the fluid through the pump. A trash pump should be switched when water stops moving through a pipe. A trash pump should not be used to pump gasoline, caustic chemicals, or other fuels due to the damage these materials can have on the pump. Safety and mechanical issues could result from this process.

It is important to check the water’s temperature when using a trash pump. High-temperature water can cause cavitation issues (where static pressure forms pockets of vapor-filled cavities in a liquid), boil when pulled in, harm the pump"s impeller, and have a high vapor pressure.

Trash pumps have special capabilities that enable them to move enormous volumes of liquids that are heavily contaminated with particles and rubbish. These abilities are a result of their components; some of these components are discussed below.

Trash pumps utilize an impeller, a revolving part of a centrifugal pump, which helps limit clogging. The impeller raises the liquid"s pressure and flow by accelerating fluids away from the rotor. The fluid"s increased pressure and flow decrease the likelihood of clogging. An impeller does not grind down the garbage and other debris; they are propelled out whole. The fibrous materials, solids, and grit are directed through the pump without grinding because of the liquid vortex the impeller generates in the casing.

A pump may become clogged if materials enter that are greater than the pump’s capacity. Strainers are installed at the inlet of trash pumps to stop debris and other materials from entering which are larger than the pump"s volume. It is also essential to make sure the strainer is always submerged for it to perform its job.

Trash pumps self-prime. The priming process is performed in order to remove air and vapor from the pump and the suction line. The priming procedure entails pushing air out of the pump and replacing it with fluid, such as water. No pumping will occur if priming is not performed. A self-primer guarantees that there is always liquid in the priming chamber. If fluid levels need to be raised before starting an engine, a switch will be activated to indicate that manual priming must be performed.

Although trash pumps all serve the same general purpose, variations exist to better serve specific applications. We examine a few trash pump varieties below.

Positive displacement pumps move fluids through pistons, gears, diaphragms, and other components. A vacuum is produced when a fluid enters their fixed chamber and is pumped out. This vacuum is also useful for moving objects. Displacement pumps work well when pumping viscous liquids under high pressure.

Syringe pumps handle materials that need precise flow rates at precise times. The two types of syringe pumps are infusion pumps, which process fluid under tightly-controlled pressures, and withdrawal pumps, which are used to remove fluids.

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Mud recycling systems were once considered optional equipment. Environmental regulations continue to become more stringent and we must all responsibly make a contribution to protect our fragile ecosystem.

Using mud recyclers are a valuable asset to drilling contractors, as well-conditioned drilling fluid can save resources, time and money by reducing the amount of water and chemicals needed by reusing your bentonite and water. This helps maintain borehole stability with consistent mud properties through the entire circulation of the fluid and you haul off mainly the drilled solids, not the entire mud returns, including the liquid.

Drillers considering a mud recycler often ask: “Where do I start?” There are factors to consider before purchasing (or renting) a mud recycler, and, just like sizing the drill rig, sizing the recycler is equally important to your success. The following are some of the questions to ask yourself before making your purchase:

These factors are important to know so that you use a recycler that is sized to clean the mud and protect the components on the rig, pump and cleaner.

Drilling rigs are generally classified as “maxi,” “midsize” and “compact. While you can put a maxi recycler with a compact rig, it would not be advisable to do the reverse. Lesson: size accordingly.

As a general rule, size the recycler cleaning capacity to one and a half to two times the pumping volume (max gpm) of the triplex pump. HDD drillers normally run thicker fluids due to the low vertical height and long horizontal lengths of their bores; thicker fluid makes it more difficult for the shakers and cones to process (separate) the solids from the liquids. This is largely due to the natural coating ability of bentonite — It wants to encapsulate the solids and “hold on” to them. By upsizing the recycler, the solid particles have a second or third opportunity to process through the mud recycler for removal before going back to the rig.

Some mud recyclers provide an “onboard” mud pump that was sized specifically to the recycler. This enables the driller to use all available drill rig horsepower toward the rotation and push-pull of the drill pipe, thereby not “robbing” it for an onboard triplex pump.

Most recyclers today use orbital, elliptical or linear motion shakers, and each has a place in different drilling scenarios. With that being said, linear motion shakers generate high G-Forces and are especially effective in shallow formation sections where high-volume, heavy solids are encountered, and have the ability to remove the solids quickly.

When choosing a linear shaker for your mud system, look for a long runway (area of length from the front of the shaker to the end where the cuttings dump off). The longer length shaker bed allows extra time for solids to separate from the liquid, and result in drier solids leaving the mud system for disposal. You can also increase the angle of the shaker bed by five degrees to further increase the travel time of the solids.

Proper shaker screen selection enhances the results of the mud recycler, and, combined with the G-Force of the shaker, works in tandem to maximize solids dryness. In the past, shaker screens were sized by mesh size.

Before buying your recycler, do your research, talk to other drillers, decide what you need and you will be able to make the best decision for you and your company.

Example: 40 mesh screen had 40 openings per square inch of screen area. As a measurement, this left room for a lot of unknown variables, including questioning what gauge wire was used in the manufacture of the screens. The wire gauge altered the size of openings on the screen surface and resulted in changing the size of the solids that the screen could pass or “cut.”

The industry needed a consistent way to measure the “cut point” of the screens, and the API introduced the D100 designation, or D100 “cut point” using the average micron cut of the shaker screen, depending on the wire. Two examples are the CRX Oblong and UF square meshes.

Identification of particle sizes from core samples taken on each drilling location provides drillers valuable information and aids in selecting screens. Drilling contractors should carry a couple of testing tools to measure the effectiveness of a of the mud recycler while drilling. These tools are: a Marsh funnel and cup, sand content kit and mud weight scales. Taking mud samples from the return pit or possum belly before the mud is processed, the underflow and overflow of the cones and the clean mud tank help monitor the effectiveness of each component of the recycler, and the driller can make component adjustments to achieve maximum efficiency.

In addition to the shale shakers, another way to size the processing capability of the mud recycler is to look at the hydrocyclone. Depending on the size of the mud recycling system, cone size will be 4, 5, 10 or 12 in. Each size cone has a micron “cut point,” and represents the size of the smallest particle the cone can “pull.” Four- and 5-in. cones have a 20-micron “cut point,” and 10- and 12-in. cones have a 74-micron “cut point.” Smaller mud systems normally have two section tanks, with a ”dirty” tank under the scalping shaker and a “clean” tank under the mud cleaner (shaker with desilting cones), while larger systems can have three section tanks with scalping, desanding and desilting.

One hydrocyclone processes liquid at a rate of 50 gpm/ 4-in. cone, 80 gpm/ 5-in. cone, and 500 gpm/ 10-in. or 12-in. cone. Some manufacturers’ volume amount for their respective cone sizes may differ than those cited herein, but these are the most common within the industry for reference purposes.

Maintaining proper pressure is essential for the hydrocyclones to work effectively, with the normal operating pressure range for 4- and 5-in. cones of 30 to 40 psi; 10- and 12-in. cones of 23 to 35 psi. Pressure above 45 to 50 psi cause premature internal cone wear, and lower pressure down around 20 to 22 psi is a “red flag” that you better consider rebuilding the centrifugal(s) to maintain pressure in the optimum range.

Borehole returns require transport into the recycler via a “trash” pump properly sized for the job. Different pumps are available, but the three most common are: 1) submersible, 2) semi-submersible, and 3) aboveground centrifugal with a foot valve. Totally submersible pumps are generally the smallest in size, have a flooded suction to help in priming, and though the most convenient option, are usually the most expensive. Semi-submersible trash pumps still have a flooded suction, but the drive motor is not submerged into the fluid. Semi-submersible pumps work well, but are heavier, and longer than the submersible pumps.  Another option is an above ground centrifugal pump with a foot valve, and once primed, is dependable and normally used on larger recyclers for their increased volume capacities.

If your drilling crew has never operated a mud recycler, be sure that you are provided with training and try renting a unit to make sure it is the right “fit” prior to purchase. Be familiar with the maintenance requirements of your mud system; usually the owner’s manual is sufficient, but inquire if the manufacturer offers training videos, onsite or plant training sessions and — the most important — technical support.

A manufacturer should stand behind the equipment its builds so don’t settle for a warranty less than one year. Ask questions about the warranty prior to finalizing the purchase.

In an age where protection of our planet is a major concern, so should your choice of mud systems. Choose a recycler that is respectful to the environment and leaves your jobsite as clean as possible.  Do your research, talk to other drillers, decide what you need and you will be able to make the best decision for you and your company.

Many pumps are available in the marketplace today for many different applications, including: sewer bypass, wellpoint dewatering, dewatering excavations, and many others. Determining the best pump to use on a particular application can be a challenging enterprise. Choosing the right pump can mean a profitable job, while on the other hand, choosing the wrong pump can spell trouble and result in costly downtime. Listed below are the some of the features to look for in a quality trash pump.

Priming and Repriming Capability – Many factors can contribute in causing a pump to lose its prime. One factor is the water level dropping in, causing the suction hose and strainer to be exposed and allow air to enter the hose. This causes many pumps to lose prime and stop pumping. Holes, tears, or improper installation of the suction hose can also contribute to the loss of prime. If the pump is not able to regain prime, the project can become unsafe, resulting in damage to equipment and personnel. Choosing the right pump depends upon overall application requirements and customer preference.

pump casing, which when filled with water before operation, will prime and reprime automatically without the aid of an auxiliary priming device. Wet prime pumps are capable of handling about 29-cfm of air. Some manufacturers use wet-priming pumps and install a priming device, such as a vacuum pump or a compressor pump to add additional air handling capability for quicker priming and repriming times.

Straight, end-suction centrifugal pumps are reliant on the use of an auxiliary priming device, such as a vacuum pump, compressor pump, or hand device to achieve and maintain prime because they are not capable of handling air on their own. If the priming system should fail, pumping cannot continue until the priming system is repaired.

Dry-priming pumps employ a wet prime, self-priming centrifugal trash pump, or an end-suction centrifugal pump. Dry-priming means that these pumps do not require the pump casing to be filled with water, as do wet-priming pumps, and rely on the air

handling capability of their automatic priming systems to remove the air from the suction line, creating a vacuum, and drawing the fluid into the pump casing. This is beneficial especially during freezing temperatures when freezing water in the volute could cause the volute to break, or having your pump far from the nearest water source, where buckets of water would have to be brought to the pump casing just to achieve prime. They are fitted with automatic priming systems such as vacuum pumps or compressor pumps, keeping the pump primed continuously. These add-on accessories are able to provide large air handling capability (especially when installed on wet-priming pumps), quicker priming times, the ability to reprime if priming water is lost, and added versatility that can truly make a difference on the job.

A vacuum-assisted priming system consists of a vacuum pump that is powered by the diesel engine; a set of wire-reinforced supply and return line hoses to provide lubricating oil to the vacuum pump; a discharge check valve to prevent air and pumping effluent from entering the pump during downtimes and; an air separator chamber with a float system to regulate the air as it enters the pump. Some vacuum pumps can provide an extra 78-cfm of air handling capability, and are an excellent addition to a wet-priming pump that has air handling capability on its own.

A compressor-assisted priming system consists of a compressor that is also powered by the diesel engine; an air separator chamber with a float system to regulate the air as it enters the pump; a discharge check valve to prevent air and pumping effluent from entering the pump during downtimes and; an air eductor, or venturi system, connected to the compressor and the air separator by a series of hoses and used to force the air to create the vacuum in the suction line. The venturi is manufactured to precise specifications and is made to only handle air.

If pumping effluent infiltrates the priming system and escapes out of the venturi, it can cause the venturi to fail and not be able to prime the pump until repaired or replaced. To replace the venturi is a major expense – so it is important to associate with a pump manufacturer who has success in keeping the pumping effluent away from the venturi, such as Thompson’s ENVIROPRIME® Priming System. Some compressor pumps can provide an extra 14-cfm of air handling capability, and are an excellent addition to a wet- priming pump that has air handling capability on its own.

Submersible pumps are submersed directly into the pumping effluent and reprime automatically when the water level covers the strainer. Sometimes, submersible pumps are attached to floatation devices, which keeps the strainer of the pump submersed, and therefore, keeps its prime.

Broad Operating Range – The flow rate into an excavation can vary from several hundreds of gallons per minute of water at the beginning stages of the job to a few gallons per minute at the later stages of the job. The right pump must be capable of handling the maximum pumping capacity to lower the groundwater table as well as operating satisfactorily at reduced flow rates to maintain the groundwater table at the desired sub-grade.

Dry Running Mechanical Seal – When the pumping effluent levels reduce, the pumping capacity will typically diminish. During these periods, the pump’s capacity can far exceed the seepage rate into the excavation causing the pump to run completely dry. Pumps are available with special seal materials such as tungsten carbide and automatic lubricating systems (grease or oil) to allow the pump to operate during long periods of dry running, operating without pumping effluent entering the pump casing, without damage.

High Suction Lift Capability – As a site is excavated below the natural groundwater table, there is the potential for a larger quantity of water to enter the excavation. Moreover, the deeper the excavation, the greater the reduction on the pump’s capacity. The right pump must be capable of pumping the required capacity at the given suction lift.

Trash Handling Capability – The water entering an excavation is often mixed with sand, rocks, sticks, etc. The right pump must be capable of passing large debris without binding or damaging the pump.

Heavy-Duty Cast Iron Construction – To ensure satisfactory life and reliability when handling trash-laden water, the pump should be constructed of heavy-duty cast iron components.

Inspection Port – Trash handling pumps are fitted with lightweight removable covers allowing easy access to the pumps interior for removal of trash, without disturbing the suction or discharge hoses.

Replaceable Wear Plate – The most expensive component of the pump by far is the pump casing. A quality trash pump incorporates a replaceable wear plate to protect the pump casing from wear and to prolong the life of the pump casing. Some wear plates are even equipped with a rubber lining to further protect the casing against abrasion.

Front Pull-Out Feature – Certain trash pumps are available with a front pull-out design. This design includes a lightweight front cover that allows access to the pump interior for removal of blockage and replacement of the internal pump components in the field without disturbing the suction or discharge hoses.

24-Hour On-Board Fuel Tank – Trash handling pumps for dewatering are required to operate continuously to keep water out of the excavation. This includes at night when the work crews have gone home. For this reason, trash-handling pumps are available with on-board fuel tanks permitting the pump to operate up to 24-house before refueling. This gives the contractor the luxury of not having to send personnel out during the night to refuel the pump.

Sound Attenuation – Sound attenuated pumps are becoming one of the strict demands of municipalities nationwide. When pumping in a highly populated area, especially when it’s required to pump into the night, sound attenuated pumps are necessary. Thompson Pump has spent years perfecting providing pumps with options that help users do their jobs easier. Thompson Pump is the only pump company with a completely removable, modular sound attenuated canopy. This allows the freedom of having the right pump for the job at hand.

Versatility & Dependability – A quality trash pump must not only have quality components, but they also must be able to be versatile enough to be used on many different applications, and dependable enough to ensure that it will perform well on those applications. Many companies depend on multi-purpose products to be able to keep costs down while being able to use that product in different applications, and increasing their revenue. The same is true with a quality trash pump. Some pump manufacturer’s trash pumps perform well on some applications, but do not perform as well on others. For example: a dry-prime trash pump with a self-priming centrifugal pump end and a high air handling capability may be used on a small wellpoint job, and also on a trash or solids application; where as an end suction centrifugal trash pump with a low air handling capability may perform well in a in a trash or solids application, but may not perform well, or at all, in a small wellpoint application.

Waste Treatment: Sewer bypasses; pumping polluted hot or corrosive wastewater containing sand, mud or solids in suspension; dosing neutralizing liquids; pumping out settled sludge

Remove water from flooded basements and construction sites, drain ponds or transport fresh water with our reliable pumps. Designed for a variety of applications, the large selection of Wacker Neuson pumps can handle clear water, water with some solid content and even mud and slurries, quickly and efficiently.

Priming assisted, centrifugal, solids-handling pumps, venturi and compressor priming system for medium to high head contractor and bypass applications

Priming assisted, centrifugal, solids-handling pumps, venturi and compressor priming system for high head/high flow contractor and bypass applications

The TP03 and TP08 lines of trash pumps are a great example of the power of hydraulics when it comes to pumping liquids with solids. The TP03 pump provides 450 gallons per minute (1688 lpm) of discharge capacity and can pump solids up to 3 inch (76 mm) in diameter. The TP08 has a 800 gpm (3028 lpm) of discharge capacityand can pump up to 4 inch (102 mm) diameter solids.

Designed to handle solids in water up to 25mm in size, the pump comes in a robust steel roll-over frame for protection on any worksite. The pump"s quick-release feature means that any debris can be quickly and easily removed from a blocked impeller, making for easy maintenance and ensuring sustained performance for years to come. It has rapid self-priming capability

Specifically designed pumps for heavy duty applications. Epoxy/polyester coated housing. Handles solids with ease and simple to open and clean. Standard roll cage protects pump and engine. Steel strainer for intake hose included. Available with either Briggs & Stratton Intek™ Pro or Honda engines.

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