duplex mud pump parts free sample

We stock fluid end parts for the5×6 mud pump, 5×6-1/4 FM45 mud pump, 5×8 mud pump, 5-1/2×8 mud pump, 5X10 mud pump, 4-1/2×5 mud pump, 7-1/2×8 mud pump, and 7-1/2X10 mud pump.  The Gardner Denver mud pump model numbers for the above pumps are as follows: 5X6-FGFXG, 5X8-FDFXX, 5-1/2X8-FDFXX, 5X10-FDFXD, 4-1/2X5-FFFXF, 7-1/2X8-FYFXX, 7-1/2X10-FYFXD.  We also handle Wheatley, Gaso, Worthington, Failing and Centerline parts and pumps. We also stock Foot Valve, Liner Puller, Valve Seat Puller, (4″ Inline Check Valve.  Our Gardner Denver mud pump parts are not only competitively priced, they are also made in the USA.  Oil Recommended by Gardner Denver.  Call any of our experienced representatives to get the help and knowledge you deserve.

The 2,200-hp mud pump for offshore applications is a single-acting reciprocating triplex mud pump designed for high fluid flow rates, even at low operating speeds, and with a long stroke design. These features reduce the number of load reversals in critical components and increase the life of fluid end parts.

The pump’s critical components are strategically placed to make maintenance and inspection far easier and safer. The two-piece, quick-release piston rod lets you remove the piston without disturbing the liner, minimizing downtime when you’re replacing fluid parts.

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AN OPERATIONAL SAFETY RELIEF VALVE MUST BE INSTALLED IN THE DISCHARGE LINE BETWEEN PUMP AND ANY OTHER PIPE FITTINGS. THIS RELIEF VALVE MUST BE SET AT THE RECOMMENDED RELIEF PRESSURE DESIGNATED ON THE PUMP APPLICATION TAG. CATASTROPHIC DESTRUCTION OF PUMP, PIPING, OR PERSONAL INJURY MAY RESULT IF DISCHARGE LINES ARE CLOSED WHEN THE PUMP IS STARTED, OR AFTER THE PUMP IS RUNNING.

Gears, connecting rod bearings and crossheads in all geared piston type pumps are lubricated by splash from lubricant in the crankcase. Crankshaft bearings and pinion shaft bearings in series 1800, 1500, 1600, 1700, 1900, and 2600 pumps are also lubricated from this same oil in the crankcase by splash. Shaft bearings in Series 1550-C, 1654-C, 2000 and 2200 pumps and in pumps with Serial Number 24523 and below are sealed off from the crankcase lubricant by oil seals and run in a separate bath of oil retained in the respective bearing housing.

WARNING -The crankcase is drained after testing pump at the factory. Remove crankcase cover or crosshead guide hand hole cover and fill with sufficient lubricant before starting the pump for the first time.

Quantity and type of lubricant required to fill crankcase to proper level is shown below. For chain and sprocket driven pumps use an SAE 30 high grade mineral oil in Crankcase.

For herringbone gear driven pumps operating in average climates, use SAE 90EP, AGMA 5EP, or AGMA 6EP gear lubricants. Be sure, however, to use an EP lubricant that will not have a corrosive action on Bronze and that it contains rust, oxidation and foam inhibitors. multi-purpose multi-viscosity gear lubricants are UNSATISFACTORY for use in GASO pumps.

For worm driven pumps, use an SAE 140 EP Gear Lubricant. Running temperature of crankcase oil should not exceed 180 degrees Fahrenheit. If higher temperatures occur and mechanical fits are found to be correct the use of a separate oil cooler is recommended. In addition, SAE EP 140 Gear Lubricant should be placed in separate bath bearings on pump where they are standard.

LUBRICATION OF SHAFT BEARINGS IN SERIES 1550-C, 16540C, 2000 and 2200 - (AND FOR PUMPS #24523 AND BELOW) These pumps are equipped with inner oil seals on pinion shaft and crankshaft, so they run in a separate bath of SAE EP 90 Gear Lubricant or SAE 50 high grade motor oil or mineral oil. The correct amount of oil is put into the bearing housings when pump is shipped from factory, but a check should be made to see that none has leaked out or been removed. Proper oil level is even with pipe plug in lower part of bearing housing flange or cover plate.

Pumps with herringbone gears #24523 and up do not have inner oil seals installed for the pinion and crankshaft bearings as standard equipment however, you pump may have these seals installed as special equipment. if your pump has inner oil seals installed, the amount of oil required for the crankcase is as follows:

To check for wear, place a wrench on the top connecting rod bolt and shake the rod parallel to the crankshaft. (The pressure must be relieved from the liquid end of the pump so that the pump"s mechanism is free to move.) If the rod bearing moves without resistance, the bearing may be too loose and need adjusting. If the bearing does need adjusting, remove shims until you cannot shake the rod, then add .005"" shims one at a time until there is a little side movement. Be sure to torque rod bolt nuts to proper value for each adjustment. (NOTE: If you are making this adjustment after having had the crossheads out, be sure that the oil holes in the rod are pointing up. The ""up"" side is indicated by matching numbers stamped on the cap and rod at the split between them. These numbers should be the same on each rod and should be on the top side of the crankshaft.) Turn the shaft by hand and if there is any hard drag or tight spots in the bearing, add another .005"" shim. After this bearing is properly adjusted, loosen bolts a few turns and repeat the above operation on the other bearings. After all bearings have been adjusted, torque all connecting rod bolt nuts back to proper amount. Again turn the pump by hand to check for excessive drag and tight spots. If none, the pump should then be ready for operation.

If the pump cannot be rotated by hand due to the drive being enclosed, the bearings may be completely adjusted by shaking the bearing on the shaft as stated above. Care must be taken not to over-tighten the bearings since they cannot be checked by rotating the pump by hand. When bearings are adjusted by this method, they must be watched carefully for overheating when the pump is put into operation.

Alternatively, plastic gauge strips, found in most parts stores may be used to adjust these bearings. It is usually better to have a bearing a little too loose than too tight. A slightly loose bearing will cause very little trouble because of the slow operating speeds of the pump, but a tight bearing will overheat and the babbitt may melt or pull. with experience, an operator can tell by feel when the bearings are properly adjusted. Normal precautions must be taken to insure cleanliness of parts upon their assembly. All wrenches used in adjusting these bearings are standard wrenches.

Bearings in the crosshead end are bronze bushings. To replace these bushings, remove connecting rod and crosshead assembly from pump. Press out the crosshead pin, and then remove and replace bushing. After the new bushing has been pressed into the connecting rod, it should be reamed for a loose fit on the crosshead pin as follows: .002"" for pumps Series 1500, 1800, and 1700, .0025"" for pumps Series 1600, and .004"" for pumps Series 2600.

Crankcase bearings for Series 1800, 1500, 1600, and 1700 pumps should have an end play in the crankshaft of: .001"" to .003"" for 1800 pumps .002"" to .004"" for 1500 pumps & 1600 pumps .003"" to .005"" for 1700 pumps

This end play is measured when pump is cold to allow for expansion due to heat under operating conditions. Bearings may be adjusted from one side only. To adjust bearings for end play, disconnect connecting rods, remove several shims (more than necessary) from under the bearing housing, tighten up on crankshaft bearing housings until bearings bind slightly when shaft is rotated by hand. Then measure the shim gap with a feeler gauge and add its equivalent plus from .001"" to .003"" of shim (for normal clearance) and tighten up on crankshaft bearing housing cap screws.

Crankshaft bearings for series 2600 Pumps have a .012"" to .013"" pre-load. To get this pre-load, try different thicknesses of shims until a slight drag is felt while rolling the shaft and then remove .012"" to .013"" of shims. When necessary to install new bearing cones on crankshaft, heat them in oil at 280 degrees Fahrenheit for easy installation. Be sure they are firmly against the shoulder on the crankshaft.

Please note: Improper application of heat to these bearings during their installation in GASO pumps will automatically revoke the warranty on the bearings. It is suggested that the procedures outlines above be closely followed when changing bearings. PINION SHAFT BEARINGS - The pinion shaft bearings are self-contained ball or roller bearings and have no adjustment for wear. Their load ratings are far above the load applied and will therefore have very little wear if properly lubricated.

Although pumps may run backwards without adversely affecting operation, always run them faster than 75 strokes per minute or install inner oil seals for pinion shaft and crankshaft bearings.

In worm-driven pumps, the main or ring gear, is of special nickel alloy bronze with internal flange for bolting to center disc of crankshaft. The driving worm and shaft is one piece, of chrome nickel steel, hardened and ground. This worm and shaft is removable through the end of worm case toward the liquid end of pump but it will first be necessary to remove the flexible coupling, stuffing box, and thrust bearing jam nut from other end of shaft. The thrust bearings will slide off when shaft is withdrawn.

Series 1550-C and 1654-C pumps use quadruple row internal sprockets with specially made heavy duty quadruple row chain. The driving pinion shaft and sprocket is one piece with Nitride Hardened sprocket teeth.

The piston rod stuffing boxes in power end of pump are packed at the factory. The purpose of this packing is to wipe the piston rod clean and thus prevent contamination of lubricant in the crankcase and also to prevent loss of oil from the crankcase. Adjust this packing by evenly tightening the packing gland cap screws until leakage is minimized.

Over a period of time, beginning may, 1978, all liquid end bodies for Duplex Piston Pumps were gradually redesigned to accept an O-ring mounted in a bevel at the opening of the valve covers, cylinder heads and stuffing boxes. This re-design allowed the flange of the valve cover, cylinder head, or stuffing box to fit metal-to-metal with the liquid body. Prior to this re-design most of these liquid ends were counter-bored to accept a flat gasket which caused a gap between the flanges of the valve covers, cylinder head, or stuffing boxes and the liquid end. BEFORE YOU REPAIR YOUR PUMP, MAKE A VISUAL CHECK TO SEE WHAT TYPE OF VALVE COVER, CYLINDER HEAD, AND STUFFING BOXES ARE ON THE PUMP.

The list of serial numbers below will serve as a general guide to the first pumps fitted with o-rings, but does not guarantee that your pump has them. You must check your pump before ordering parts for it. The first number is the pump serial number, the second number is the liquid end serial number:

Liquid end stuffing boxes on a new pump must be packaged by the user before the pump is put into service. The necessary packing will be found in small sacks packed in a box with other pump accessories. Standard packing consists of lip type packing rings. These function best when not squeezed up too tight. Special packing sometimes furnished consists of square graphited duck and rubber packing rings. These require more pressure to seal off fluid satisfactorily, but care should be exercised to avoid over-tightening. Good practice is to let packing leak slightly.

Standard pistons for crude oil service consist of cast iron or steel bodies with special patented cast iron porous chrome faced piston rings. Cast iron or steel piston bodies with nylon glass filled piston rings are furnished pumping crude oil products. Cup type pistons are furnished for pumping saltwater and rubber inserted pistons are used for slush and cementing service.

To replace pistons, remove crosshead jam nuts and power end and liquid end stuffing box glands and packing. Remove cylinder heads and pull rod, piston and liner through front of liquid end. Install new pistons, rings or cups is required. Insert pistons on to rod and into liners, oriented with front of piston toward flange end of liner. Install new liner gasket, and slip liner, piston and rod assembly into pump. Be sure to slip packing glands over rod before pushing rod thru power end stuffing box. Run crosshead jam nut onto rod as far as possible, positioned so flat face of nut will bear upon face of crosshead. Run rod into crosshead until jam nut touches crosshead, then tighten jam nut against crosshead. Be sure all mating surfaces are dry and clean before tightening nuts against pistons or crossheads. Note: torque all nuts holding pistons to rod to 7.200 in.-lbs.

Holding liner in place, roll pump one complete revolution to verify that piston is centered in the liner (end of cast iron piston may stroke out of liner), and adjust as necessary by repositioning the crosshead jam nut on the rod. Once centered, install the packing, glands, and cylinder heads. (See instructions for tightening liner set screws below.) Slush type pistons generally require more frequent attention than other types of pistons.

standard liners for crude oil service are cast iron. Liners for saltwater service are corrosion resistant material. Hardened steel liners are recommended for slush pump service. Always use new gaskets when changing liners.

There are four Liner Set Screws with jam nuts in each cylinder head. These are to hold the liner against the liner gasket. When installing cylinder head, back the liner set screws out a little and then tighten all nuts on cylinder head studs first. Be sure to work around the cylinder head from nut to nut until all are tightened evenly. Then tighten set screws against the liner, torque to 2880 in.-lbs. with the exception of Fig. 1849 pumps which are torqued to 2400 in.-lbs. again working evenly. Lastly, tighten the jam nuts on these set screws. Be sure that packing or lead gasket is in the cupped space on underside of jam nut.

Standard equipment for crude oil service consists of hardened and ground steel wing guided valves and seats. Bronze wing guided valves and seats are usually furnished for fresh or saltwater service. Tops of valve stems are slotted so that valve can be rotated in the pump to regrind valve and seat faces with grinding compound. When worn too badly, they can be removed and faced off in a lathe.

Slush pump valves require frequent replacement of rubber inserts due to the very abrasive material being pumped. Valves and seats should be inspected before starting and when finishing any drilling job. When replacing valve seats, clean valve seat and mating taper in liquid end with a cleaner that does not leave an oil film or residue. Wipe with a clean, dry rag.

Note: If the pump is EVER overloaded (loaded above maximum recommended published pressures) or if a stud EVER fails for any reason whatsoever, REPLACE ALL STUDS IN THE LIQUID BODY BEFORE USING THE PUMP AGAIN.

Pumps are equipped with O-Ring gaskets for valve covers, cylinder heads, and stuffing boxes, and with flat fiber gaskets for suction and discharge flanges. Separate lantern rings and ""tattle-tale"" packing is furnished as gaskets for liners in recently manufactured slush fitted pumps, while pumps fitted for other applications are equipped with spacers and flat fiber liner gaskets. Always be sure that all gasket surfaces are smooth and dry and free of any particles which would scratch or otherwise interfere with efficient operation of the gasket.

Piston displacement and recommended working pressure for continuous duty and with various size liners are shown in the current GASO catalog. When pumping relatively incompressible liquids, volumetric efficiency of pump when valves and liners and pistons are in good shape should be from 95% to 96%. If actual output of pump does not equal 95% of displacement figures shown at the respective speeds, cause o£ trouble may be foreign matter lodged under valve, bad valve facing, worn liners, worn piston rings, or blown liner gasket. Too small a suction line may also be cause of shortage. SUCTION LINES -- (REFER TO DIAGRAM)

Flush suction lines thoroughly before starting pump. Always provide ample capacity suction lines to the pump. This is the first requisite when installing a GASO pump. The pump cannot function properly if an inadequate quantity of fluid is furnished it. For suction lines leading directly to the pump, select a size line so that the velocity of the fluid will not exceed 12 feet per second, or one that is two sizes larger than the pump suction connection, whichever gives the slower line velocity. The last to to 15 feet of this line is preferably flexible hose and should always be connected to the pump inlet with an eccentric reducer (with straight portion on top). Always size ""headers"" feeding more than one pump so that the maximum velocity in the header with all pumps running will not exceed 1 foot per second.

NEVER USE PLUG-TYPE VALVES IN A SUCTION LINE. USE FULL OPENING VALVES. Keep the number of turns to a minimum. When turns are required, use long radius ells. In pumping gasoline or light volatile liquids such as butane and propane, design your system so that the positive suction head at the pump is at least 35 pounds per square inch (psi) above the vapor pressure of the fluid. When pumping water or average crude oils, 10 to 15 psi gauge pressure at the pump will usually be sufficient if pump speed does not exceed 54 RPM. If pump is running at higher speeds, provide for a minimum additional pressure of 15 psi at the pump inlet. Always connect to two sides of pumps with multiple suction inlets. This will help insure proper filling of the pump. If unable to connect to two sides, use a properly sized suction stabilizer, mounted and charged according to instructions with stabilizer.

Mud pumps are the pumps deployed in the oil and gas industry, mainly to circulate drilling fluids and other kinds of fluids in and out of the drilled wells for exploration. The mud pumps transfer the fluids at a very high pressure inside the well using the piston arrangement. The number of pistons decides the displacement and efficiency of working of the mud pumps, originally only dual piston pumps and three-piston pumps were used, but the technological advancements have seen pumps with five and six pistons to come up. Currently the triplex pumps which have three pistons are used, but the duplex pumps having two pumps are still deployed in the developing countries.

Based on its types, global mud pump market can be segmented into duplex, triplex, and others. The triplex mud pumps will dominate the mud pump marking in the given forecast period owing to its advantages and ongoing replacement of duplex pumps with triplex pumps. Based on operation, the global mud pumps market can be segmented into electric and fuel engine.

The electric mud pumps will dominate the market during the given forecast period due to the advantage of eliminating the harmful carbon emission which is done in the case of fuel engine pumps. Based on its application, the global mud pumps market can be segmented into oil & gas, mining, construction, and others.

The major market driver for the global mud pumps market is the increasing exploration activities taking place in various regions of the world to satisfy the increased energy demand. The number of drilled wells has increased in recent years, which has certainly impacted the growth of the mud pumps market in both oil & gas and mining sectors.

Key market restraint for the global mud pumps market is the drift towards the cleaner sources of energy to reduce the carbon emissions, which will certainly decrease the demand for oil & gas and therefore will have a negative impact on the growth of the global mud pumps market.

Some of the notable companies in the global mud pump market are Mud King Products, Inc. Gardner Denver Pumps, Weatherford, Schlumberger, National Oilwell Varco, China National Petroleum Corporation, Flowserve Corporation, MHWirth, American Block, Herrenknecht Vertical Gmbh, Bentec GmbH Drilling & Oilfield Systems, Drillmec Inc, Sun Machinery Company, Shale Pumps, and Dhiraj Rigs.

The global mud pump market has been segmented into North America, Europe, Asia Pacific, Latin America, and Middle East & Africa. Owing to the well-established production sector and stable exploration industry North America holds the largest market for the mud pumps. The onshore exploration activities of oil & gas have increased at a good rate in the North America region, which has certainly boosted the growth of the mud pumps market in the region.

The demand from Europe and Asia Pacific has also increased due to exploration activities in both the regions owing to the increased energy demand. The energy demand specifically in the Asia Pacific has increased due to the increased population and urbanization. The Middle East and Africa also hold significant opportunities for the mud pumps market with increased exploration activities in the given forecast period.

In August 2018, Henderson which is a leading company in sales and service of drilling rigs, and capital drilling equipment in Texas signed a contract with Energy Drilling Company for the purchase and upgrade of oil field equipment’s which included three 1600hp × 7500psi mud pumps. This will be the first refurbishment completed at Henderson’s new service center and rig yard.

In January 2018, Koltek Energy Services launched the 99-acre facility for the testing of the oil field equipment in Oklahoma. This will allow the oil field equipment manufacturers to test their equipment at any given time. The company has deployed the MZ-9 pump which has a power rating of 1000Hp.

For drilling companies with the need to pump slurries with bentonite, concrete, and other thick mud, Elepump triplex, high pressure piston mud pumps are the ideal choice for long life and minimal maintenance.

Featuring superior construction and high quality materials, Elepump mud pumps are built to last. They require minimal maintenance, so your costs stay low so and your drilling operations stay profitable.

The KT-45 mud pump is the most compact of the whole range of Elepump pressure pumps. This small capacity pump is still mighty enough to pack a big punch, with enough flow for drilling up to HQ sizes. It is very light and very maneuverable, making it a great choice for geotechnical drilling, fly jobs or heliportable jobs. Elepump mud pumps can be configured for diesel, gas, electric and air power.

The KF-50M is the pump to choose if you want a pump you can count on to keep pumping without missing a beat. This powerful pump is a standard size and can handle all slurries including bentonite, concrete and more. With its stainless steel ball and seat style valves, it is the ideal choice for pumping grit, cement, chunks of rock and other hard material, without the worry of damage to fragile parts. Elepump mud pumps can be configured for diesel, gas, electric and air power.

A mud pump is a reciprocating piston/plunger pump designed to circulate drilling fluid under high pressure (up to 7,500 psi (52,000 kPa)) down the drill string and back up the annulus. A duplex mud pump is an important part of the equipment used for oil well drilling.

Duplex mud pumps (two piston/plungers) have generally been replaced by the triplex pump, but are still common in developing countries. Two later developments are the hex pump with six vertical pistons/plungers, and various quintuplex’s with five horizontal piston/plungers. The advantages that Duplex mud pumps have over convention triplex pumps is a lower mud noise which assists with better Measurement while drilling and Logging while drilling decoding.

Use duplex mud pumps to make sure that the circulation of the mud being drilled or the supply of liquid reaches the bottom of the well from the mud cleaning system. Despite being older technology than the triplex mud pump, the duplex mud pumps can use either electricity or diesel, and maintenance is easy due to their binocular floating seals and safety valves.

A mud pump is composed of many parts including mud pump liner, mud pump piston, modules, hydraulic seat pullers, and other parts. Parts of a mud pump:housing itself

Duplex pumps are used to provide a secondary means of fuel transfer in the event of a failure of the primary pump. Each pump in a duplex set is sized to meet the full flow requirements of the system. Pump controllers can be set for any of the following common operating modes:Lead / Lag (Primary / Secondary): The lead (primary) pump is selected by the user and the lag (secondary pump operates when a failure of the primary pump is detected.

Alternating: Operates per Lead / Lag (Primary / Secondary) except that the operating pump and lead / lag status alternate on consecutive starts. A variation is to alternate the pumps based on the operating time (hour meter) of the lead pump.