Difference between revisions of "Progressive Cavity Pumps"
m |
|||
Line 1: | Line 1: | ||
[[Category:Pumps]]{{Knoppen}} | [[Category:Pumps]]{{Knoppen}} | ||
[[File:Progressive cavity pump.jpg|thumb|right|Progressive Cavity Pumps]] | [[File:Progressive cavity pump.jpg|thumb|right|Progressive Cavity Pumps]] | ||
'''Progressive Cavity Pumps''' are of [[Positive Displacement Pumps]] and are also known as [[Progressive Cavity Pumps]], eccentric screw pump or cavity pump. It transfers fluid by means of the progress, through the pump, of a sequence of small, fixed shape, discrete cavities, as its rotor is turned. This leads to thevolumetric flow rate being proportional to the rotation rate and to low levels of shearing being applied to the pumped fluid. Hence these [[Pumps]] have application in fluid metering and pumping of viscous or shear-sensitive materials. The cavities taper down toward their ends and overlap with their neighbours, so that, in general, no flow pulsing is caused by the arrival of cavities at the outlet, other than that caused by compression of the fluid or pump components. | '''Progressive Cavity Pumps''' are of [[Positive Displacement Pumps]] and are also known as [[Progressive Cavity Pumps]], eccentric screw pump or cavity pump. It transfers fluid by means of the progress, through the pump, of a sequence of small, fixed shape, discrete cavities, as its rotor is turned. This leads to thevolumetric flow rate being proportional to the rotation rate and to low levels of shearing being applied to the pumped fluid. Hence these [[Pumps]] have application in fluid metering and pumping of viscous or shear-sensitive materials. The cavities taper down toward their ends and overlap with their neighbours, so that, in general, no flow pulsing is caused by the arrival of cavities at the outlet, other than that caused by compression of the fluid or pump components. | ||
Line 20: | Line 13: | ||
The rotor takes a form similar to a corkscrew, and this, combined with the off-center rotary motion, leads to the alternative name: eccentric screw pump.Different rotor shapes and rotor or stator pitch ratios exist, but are specialized in that they don't generally allow complete sealing, so reducing low speed pressure and flow rate linearity, but improving actual flow rates, for a given pump size, and/or the pump's solids handling ability. | The rotor takes a form similar to a corkscrew, and this, combined with the off-center rotary motion, leads to the alternative name: eccentric screw pump.Different rotor shapes and rotor or stator pitch ratios exist, but are specialized in that they don't generally allow complete sealing, so reducing low speed pressure and flow rate linearity, but improving actual flow rates, for a given pump size, and/or the pump's solids handling ability. | ||
==Operation of Progressive Cavity Pumps== | ==Operation of Progressive Cavity Pumps== | ||
In operation progressive cavity pumps are fundamentally fixed flow rate pumps, like [[Piston Pumps]] and [[Peristaltic Pumps]], and this type of pump needs a fundamentally different understanding to the types of [[Pumps]] to which people are more commonly first introduced, namely ones that can be thought of as generating pressure. This can lead to the mistaken assumption that all pumps can have their flow rates adjusted by using a valve attached to their outlet, but with this type of pump this assumption is a problem, since such a valve will have practically no effect on the flow rate and completely closing it will involve very high pressures being generated. To prevent this, pumps are often fitted with cut-off pressure switches, burst disks , or a bypass pipe that allows a variable amount a fluid to return to the inlet. With a bypass fitted, a fixed flow rate pump is effectively converted to a fixed pressure one. | In operation progressive cavity pumps are fundamentally fixed flow rate pumps, like [[Piston Pumps]] and [[Peristaltic Pumps]], and this type of pump needs a fundamentally different understanding to the types of [[Pumps]] to which people are more commonly first introduced, namely ones that can be thought of as generating pressure. This can lead to the mistaken assumption that all pumps can have their flow rates adjusted by using a valve attached to their outlet, but with this type of pump this assumption is a problem, since such a valve will have practically no effect on the flow rate and completely closing it will involve very high pressures being generated. To prevent this, pumps are often fitted with cut-off pressure switches, burst disks , or a bypass pipe that allows a variable amount a fluid to return to the inlet. With a bypass fitted, a fixed flow rate pump is effectively converted to a fixed pressure one. | ||
Line 25: | Line 20: | ||
At the points where the rotor touches the stator, the surfaces are generally traveling transversely, so small areas of sliding contact occur. These areas need to be lubricated by the fluid being pumped . This can mean that more torque is required for starting, and if allowed to operate without fluid, called run dry, rapid deterioration of the stator can result. | At the points where the rotor touches the stator, the surfaces are generally traveling transversely, so small areas of sliding contact occur. These areas need to be lubricated by the fluid being pumped . This can mean that more torque is required for starting, and if allowed to operate without fluid, called run dry, rapid deterioration of the stator can result. | ||
While progressive cavity pumps offer long life and reliable service transporting thick or lumpy fluids, abrasive fluids will significantly shorten the life of the stator. However, slurries can be pumped reliably if the medium is viscous enough to maintain a lubrication layer around the particles and so protect the stator. | While progressive cavity pumps offer long life and reliable service transporting thick or lumpy fluids, abrasive fluids will significantly shorten the life of the stator. However, slurries can be pumped reliably if the medium is viscous enough to maintain a lubrication layer around the particles and so protect the stator. | ||
==Typical design of Progressive Cavity Pumps== | ==Typical design of Progressive Cavity Pumps== | ||
Specific designs involve the rotor of the pump being made of a steel, coated with a smooth hard surface, normally chromium, with the body made of a molded elastomer inside a metal tube body. The elastomer core of the stator forms the required complex cavities. The rotor is held against the inside surface of the stator by angled link arms, bearings allowing it to roll around the inner surface . Elastomer is used for the stator to simplify the creation of the complex internal shape, created by means of casting, which also improves the quality and longevity of the seals by progressively swelling due to absorption of water and/or other common constituents of pumped fluids. Elastomer or pumped fluid compatibility will thus need to be taken into account. | Specific designs involve the rotor of the pump being made of a steel, coated with a smooth hard surface, normally chromium, with the body made of a molded elastomer inside a metal tube body. The elastomer core of the stator forms the required complex cavities. The rotor is held against the inside surface of the stator by angled link arms, bearings allowing it to roll around the inner surface . Elastomer is used for the stator to simplify the creation of the complex internal shape, created by means of casting, which also improves the quality and longevity of the seals by progressively swelling due to absorption of water and/or other common constituents of pumped fluids. Elastomer or pumped fluid compatibility will thus need to be taken into account. | ||
Two common designs of stator are the equal-walled and the unequal-walled. The latter, having greater elastomer wall thickness at the peaks allows larger-sized solids to pass through because of its increased ability to distort under pressure. The former have a constant elastomer wall thickness and therefore exceed in most other aspects such as pressure per stage, precision, heat transfer, wear and weight. They are more expensive due to the complex shape of the outer tube. | Two common designs of stator are the equal-walled and the unequal-walled. The latter, having greater elastomer wall thickness at the peaks allows larger-sized solids to pass through because of its increased ability to distort under pressure. The former have a constant elastomer wall thickness and therefore exceed in most other aspects such as pressure per stage, precision, heat transfer, wear and weight. They are more expensive due to the complex shape of the outer tube. | ||
==Sources== | ==Sources== | ||
[http://en.wikipedia.org/wiki/Progressive_cavity_pump Wikipedia Progressive Cavity Pump] | [http://en.wikipedia.org/wiki/Progressive_cavity_pump Wikipedia Progressive Cavity Pump] |
Latest revision as of 01:46, 23 December 2013
Progressive Cavity Pumps are of Positive Displacement Pumps and are also known as Progressive Cavity Pumps, eccentric screw pump or cavity pump. It transfers fluid by means of the progress, through the pump, of a sequence of small, fixed shape, discrete cavities, as its rotor is turned. This leads to thevolumetric flow rate being proportional to the rotation rate and to low levels of shearing being applied to the pumped fluid. Hence these Pumps have application in fluid metering and pumping of viscous or shear-sensitive materials. The cavities taper down toward their ends and overlap with their neighbours, so that, in general, no flow pulsing is caused by the arrival of cavities at the outlet, other than that caused by compression of the fluid or pump components.
These pumps are often referred to by the specific manufacturer or product names. Hence names can vary from industry to industry and even regionally; examples include: Moineau , Mono pump, Moyno pump, Mohno pump. A progressive cavity pump also can act as a motor when fluid is pumped through the interior. Applications include well drilling.
Theory
The progressive cavity pump consists of a helical rotor and a twin helix, twice the wavelength and double the diameter helical hole in a rubber stator. The rotor seals tightly against the rubber stator as it rotates, forming a set of fixed-size cavities in between. The cavities move when the rotor is rotated but their shape or volume does not change. The pumped material is moved inside the cavities.
The principle of this pumping technique is frequently misunderstood. Often it is believed to occur due to a dynamic effect caused by drag, or friction against the moving teeth of the screw rotor. In reality it is due to the sealed cavities, like a piston pump, and so has similar operational characteristics, such as being able to pump at extremely low rates, even to high pressure, revealing the effect to be purely positive displacement .
At a high enough pressure the sliding seals between cavities will leak some fluid rather than pumping it, so when pumping against high pressures a longer pump with more cavities is more effective, since each seal has only to deal with the pressure difference between adjacent cavities. Pumps with between two and a dozen cavities exist.When the rotor is rotated, it rolls around the inside surface of the hole. The motion of the rotor is the same as the smaller Gears of a planetary gearssystem. As the rotor simultaneously rotates and moves around, the combined motion of the eccentrically mounted drive shaft is in the form of a hypocycloid. In the typical case of single-helix rotor and double-helix stator, the hypocycloid is just a straight line. The rotor must be driven through a set of universal joints or other mechanisms to allow for the movement.
The rotor takes a form similar to a corkscrew, and this, combined with the off-center rotary motion, leads to the alternative name: eccentric screw pump.Different rotor shapes and rotor or stator pitch ratios exist, but are specialized in that they don't generally allow complete sealing, so reducing low speed pressure and flow rate linearity, but improving actual flow rates, for a given pump size, and/or the pump's solids handling ability.
Operation of Progressive Cavity Pumps
In operation progressive cavity pumps are fundamentally fixed flow rate pumps, like Piston Pumps and Peristaltic Pumps, and this type of pump needs a fundamentally different understanding to the types of Pumps to which people are more commonly first introduced, namely ones that can be thought of as generating pressure. This can lead to the mistaken assumption that all pumps can have their flow rates adjusted by using a valve attached to their outlet, but with this type of pump this assumption is a problem, since such a valve will have practically no effect on the flow rate and completely closing it will involve very high pressures being generated. To prevent this, pumps are often fitted with cut-off pressure switches, burst disks , or a bypass pipe that allows a variable amount a fluid to return to the inlet. With a bypass fitted, a fixed flow rate pump is effectively converted to a fixed pressure one.
At the points where the rotor touches the stator, the surfaces are generally traveling transversely, so small areas of sliding contact occur. These areas need to be lubricated by the fluid being pumped . This can mean that more torque is required for starting, and if allowed to operate without fluid, called run dry, rapid deterioration of the stator can result. While progressive cavity pumps offer long life and reliable service transporting thick or lumpy fluids, abrasive fluids will significantly shorten the life of the stator. However, slurries can be pumped reliably if the medium is viscous enough to maintain a lubrication layer around the particles and so protect the stator.
Typical design of Progressive Cavity Pumps
Specific designs involve the rotor of the pump being made of a steel, coated with a smooth hard surface, normally chromium, with the body made of a molded elastomer inside a metal tube body. The elastomer core of the stator forms the required complex cavities. The rotor is held against the inside surface of the stator by angled link arms, bearings allowing it to roll around the inner surface . Elastomer is used for the stator to simplify the creation of the complex internal shape, created by means of casting, which also improves the quality and longevity of the seals by progressively swelling due to absorption of water and/or other common constituents of pumped fluids. Elastomer or pumped fluid compatibility will thus need to be taken into account.
Two common designs of stator are the equal-walled and the unequal-walled. The latter, having greater elastomer wall thickness at the peaks allows larger-sized solids to pass through because of its increased ability to distort under pressure. The former have a constant elastomer wall thickness and therefore exceed in most other aspects such as pressure per stage, precision, heat transfer, wear and weight. They are more expensive due to the complex shape of the outer tube.