CN1036088C - Multi-action variable vane pump and motor - Google Patents

Multi-action variable vane pump and motor Download PDF

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CN1036088C
CN1036088C CN 92102268 CN92102268A CN1036088C CN 1036088 C CN1036088 C CN 1036088C CN 92102268 CN92102268 CN 92102268 CN 92102268 A CN92102268 A CN 92102268A CN 1036088 C CN1036088 C CN 1036088C
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slide blocks
motor
circular arc
pump
rotor
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CN1077254A (en
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许连焕
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Abstract

The invention relates to an oil pump and an oil motor in the field of hydraulic transmission machinery, in particular to a double-acting and multi-acting variable vane pump and a motor. The stator ring is characterized in that a traditional stator ring is disassembled, each circular arc and curve of the inner wall of the stator ring are respectively composed of each block body, the stator ring is placed in a pump shell inner cavity with a corresponding shape, the block bodies with the short-radius circular arcs and the transition curves are fixed, the block bodies with the same radius circular arcs are moved, the volumes of a pump and a motor are changed, and the purpose of changing the variables is achieved. The invention can be applied to wheel oil motors, hydraulic drive axles and hydraulic gearboxes of hydraulic transmission automobiles, and can be simultaneously and widely applied to all mechanical fields needing transmission and speed change.

Description

Multi-function variable vane pump and motor
The present invention relates to the oil pump and the oil motor in hydraulic machinery field, is a kind of double-action and multi-function variable vane pump and motor.
In the prior art field, double-function variable vane pump described in the CN89202985.4 that announced on February 7th, 89, it comprises main shaft, the pump housing, pressure side plate, stator with equal height and internal surface curved surface, blade, rotor, pump cover, stroking mechanism with equal height and thickness, be equipped with lining on the cylindrical of two stators, be equipped with port plate between two stators, two rotors lay respectively at the port plate both sides, stroking mechanism can promote two stators effectively and move, and has realized the variable adjusting.This kind structure comes down to be made up of two single action variable vane pump doubly-linkeds, and its shortcoming is a main shaft radial force imbalance, complex structure, and parts wear and tear easily, and rotating speed and pressure are carried not high.
The object of the present invention is to provide a kind of multi-function variable vane pump and motor, realize the adjusting of multiaction variable by the stator circle is disintegrated.
The objective of the invention is to be achieved by the following scheme: the multiaction variable vane motor includes main shaft, the pump housing, be arranged in the stator of housing, be installed in the rotor on the main shaft, several radial grooves are arranged on the rotor, one group of blade is contained in the radial groove slidably, the stator that is arranged in housing is the slide blocks that has the semi major axis circular arc camber by two, two sliding seats with short radius circular arc camber, eight transition plates with transition curve curved surface are formed, two slide blocks rotations that shape is identical are symmetrically placed in the left and right sides that is positioned at rotor in the housing, two sliding seat rotations that shape is identical are symmetrically fixed on inner walls and are positioned at rotor both sides up and down, the two ends up and down of two slide blockss are close to the two ends, the left and right sides of two sliding seats respectively, and the folding that can make the change motor displacement on sliding seat is moved, realize the purpose of variable, eight transition plates are set in the dovetail groove of short radius circular arc camber the right and left of two sliding seats.
The birth of multiaction variable vane motor makes hydralic drive automobile become a reality far and away.Because the slewing range and the low speed torque of this motor are all bigger, and it is simple in structure durable, easy to manufacture, therefore, its application area is very extensive, on the hydraulic transmission vehicle, both can be used as the all-wheel powered wheel motor, also but duplex is formed hydraulic ransaxle, or form hydraulic gearbox with variable displacement pump, can be directly on Light-duty Vehicle or motorcycle and quantitative vane pump, gear pump, plunger pump is supporting, and the application of the present invention on automobile can be cancelled original clutch, gearbox, transmission shaft and ransaxle, and original whole braking system, make the structure of vehicle become simple, durable, safe and reliable.The present invention can be widely used in each mechanical field that all need transmission and speed change simultaneously.
Accompanying drawing:
Fig. 1 double-function variable vane pump and motor schematic diagram
Fig. 2 double-action variable vane motor servo valve schematic diagram
Fig. 3 adds fourth shape blade schematic diagram
Fig. 4 four actuation variable sliding-vane motor schematic diagrams
When Fig. 5 radial dimension was restricted, double-action variable vane motor schematic diagram 1. sliding shoes 2. sliding seats 3. rebounds 4. servo valves 5. breach 6. housings 7. spools 8. valve pockets 9. differential pressures were overlapped 11. months v notch vs 12. of 10. balancing springs and are advanced sleeping hook 27. baffle plates of 19. pairs of blades of four oil holes, 13. equal pressure passageway 14. high pressure oil input channel 15. low pressure back oil roads, 16. back pressure chamber 17. low-pressure chambers, 18. primary blades, 20. rotors, 21. anchor shape pieces, 22. pump cases, 23. sieve keyholes, 24. balance oil ducts, 25. valve pins, 26. spools 28. draining roads 29. adjusting oil ducts, 30. oil input channels
Embodiment: the structure of above-described multiaction variable vane motor can be made into multi-function variable vane pump.Introduce the structure and the working principle of double-function variable vane pump and motor below in conjunction with accompanying drawing.
The circular arc of two segment length's radius Rs respectively by the right and left movably slide blocks (1) constitute, the circular arc of two sections short radius r is respectively by middle the convex formation of two sliding seats (2) up and down.Article four, transition curve is made of 8 transition plates (3) respectively, except the circular arc of two segment length's radiuses can move do folding with both sides slide blocks (1), just maintains static after remaining circular arc and transition curve assembling finish.Transition plate is sleeved on the sliding seat, can adopt dovetail mount to connect, and sees Fig. 3,5, also can adopt pin to connect, and sees Fig. 1, or directly and sliding seat make integral body (the small-power pump is made integral body) and form anchor shape piece, see Fig. 4.The transition curve of transition plate joins with short radius circular arc r respectively, intersects as Fig. 1 with the semi major axis circular arc R, and along with the folding of slide blocks is moved, its position of intersecting point also relatively moves, and narrates the structure and the principle of each parts of variable displacement pump below respectively.
One, slide blocks (1)
Two slide blockss (1) that have semi major axis circular arc and curved surface place pump case (6) lining to be positioned at the both sides of rotor, see Fig. 1, and its upper and lower end is adjacent to airfoil sliding seat (2) respectively, and can move left and right.The front of slide blocks (towards the one side of rotor) is a circular arc or curve, slide blocks last protuberance behind is close on the step of pump case inwall, slide blocks following protuberance behind is close to an end of lower slider seat, up and down protuberance directly with pump case composition back pressure chamber (16), the volume that is changing back pressure chamber is moved in the folding of slide blocks, the corner of protuberance has groove up and down, see Fig. 2, blade or Stamping Steel Ribbon are housed in the groove, in order to guarantee the sealing of back pressure chamber (16), servo valve is installed in following protuberance intermediate portion, and is drilled with into oil drain passage.Slide blocks front up and down most advanced and sophisticated position is milled with (5) 4 of the breach of position symmetry, sees Fig. 1, and the slide blocks on both sides has 8 breach, holds 8 transition plates respectively, in order to improve the performance of pump or motor, certain valve is housed also on the slide blocks, does not draw among the figure.When radial dimension was restricted, protuberance can remove under the slide blocks of variable displacement motor, sees Fig. 5, at this moment, the static pressure imbalance will appear in slide blocks, must reach partial equilibrium by the trench design of slide blocks upper and lower end face, to reduce the static friction and the kinetic friction of end face.
Two, sliding seat (2)
Sliding seat can be an airfoil, sees Fig. 1, also can be flat shape, and this example adopts wing-shaped structure, and the sliding seat bottom shape is relevant with the pump case volume, and irrelevant with pump performance, the middle upper portion of sliding seat is a convex, and the convex surface is a circular arc concave surface.This circular arc is the short radius circular arc on the conventional variable displacement pump stator, and the radius of circular arc is slightly larger than the radius of rotor, and and the rotor of this pump concentric, its arc length determines the number of blade on this pump rotor, and it is many more that the master of variable displacement pump pays blade, and this arc length is short more, blade is few more, and arc length is long more.Arc length is between the angle of two blades, and is suitable can satisfy being sealed into of high low pressure chamber, sees Fig. 3.If cooperate with the transition plate that has dovetail mount, sliding seat convex both sides should be milled with dovetail groove, see Fig. 3, Fig. 5, if cooperate with the transition plate that has pin-and-hole, sliding seat convex both sides respectively are milled with 2 breach, and fixing pin is housed, see Fig. 1 (pin does not draw), under the airfoil sliding seat both sides wing of Fig. 1 the adjustment pad is housed,, is beneficial to the sealing of back pressure chamber in order to adjust the gap of sliding seat and slide blocks rubbing surface.
Three, transition plate (3)
The slip of the epitrochanterian blade of variable displacement pump from the semi major axis circular arc to the short radius circular arc will be through having the transition curve plate of certain curved surface, transition plate is sleeved on the sliding seat with pin or dovetail mount, be movable assembling type, the wearing and tearing back is replaceable, short radius circular arc on a end on the transition plate curved surface and the adjacent sliding seat convex joins, semi major axis circular arc (or curve) on the other end of curved surface and the adjacent slide blocks intersects, its intersection point changes with moving of slide blocks, transition plate has been arranged, blade just can carry out the transition to the short radius circular arc smoothly from semi major axis circular arc (or curve), the shape of transition plate top-surface camber and length are determining the quality of blade sliding capability, impact when the curved surface of excellent in design can make vanes cross intersection point drops to bottom line, adopt the pressure of flow channel process balance blade root that blade is seamlessly transitted, effectively reduce the wearing and tearing of fillet surface.This point is even more important in four actuation variable motors, in fact, in the constant flow paddle pump of routine, the wearing and tearing of its pumping cavity fillet surface are than the serious wear of oil suction chamber fillet surface, this phenomenon is just in time opposite with expert's theory, the cause of this chances are the vane pump pumping cavity is subjected to effect of hydraulic card clamping force, hydraulic card clamping force is pressed on the fillet surface of stator blade, the withdrawal of blade is subjected to serious obstruction, thereby cause the wearing and tearing of fillet surface and rotor cell wall, influence the life-span of vane pump.The present invention uses transition plate blade is maked somebody a mere figurehead in transition region, substantially avoided the hydraulic card clamping force of new and old blade, the present invention adopts up-to-date root of blade balance method simultaneously, the method can overcome high speed centrifugation power, inertial force and the hydraulic card clamping force of blade, and blade is minimized the frictional force of transition curve in oil-feed district and laminated oil zone.
Four, servo valve (4)
Several different methods has been moved in the folding of control slide blocks, and this example is only stressed the structure and the principle of servo valve formula controlling method:
Servo valve is contained in slide blocks and descends behind in the circular hole of protuberance, its valve body compresses with sieve cover, spool is withstood by cluster spring, see Fig. 2, valve body is formed by stacking by a valve pocket (8) and two differential pressure covers (9), use as oil hydraulic motor, valve pocket (8) is a cylindrical body just, use as variable displacement pump, be milled with breach on valve pocket (8) inwall, and the breach on the spool (7) is shorter, the servo valve that is to say variable displacement pump and variable displacement motor can not be general, its difference only is the exchange of oil-feed breach (1) position, what variable displacement motor used in addition is stage clip (can be wall scroll stage clip or the cluster spring more than two), variable displacement pump can be used extension spring, also can use stage clip, if must join a spring overcoat with stage clip, this cover is fixed on the housing (6), and can regulate, spring is contained in the cover, one end of spool lengthening passes from cover and stage clip, and with card and spring abutment pressing spring, this structure is similar with being connected of motor porthole and valve spring, to move be opposite in the folding of slide blocks during the work of variable displacement pump and variable displacement motor, therefore requires the balance spring force direction of servo valve opposite, and it is extension spring that spring overcoat has played the transformation spring just.
The servo valve structural similarity of variable displacement pump and variable displacement motor, principle is opposite.This example is only narrated the working principle of variable displacement motor servo valve among Fig. 2:
High pressure oil is entered in the annular chamber in the differential sleeve through the oil inlet hole on the differential sleeve of the left side by high-pressure oil duct (14), because the annular chamber of the right differential sleeve (9) leads to low pressure chamber (leading to oil outlet), just have an annular pressure difference to act on the left end of spool (7) this moment, spool is moved right, compression balance spring (10), the spool appropriate location that moves right, two months v notch vs (11) on the spool just communicate with the low pressure circular groove on the right, and the fluid of back pressure chamber (16) lining is through all pressures intercommunicating pore (13) the oil inlet and oil return through hole (12) in the spool (7) at this moment, month v notch v (11), right annular chamber, low pressure back oil road (15), low pressure chamber (17) is until return tube.The fluid of back pressure chamber (16) is in case reduce, slide blocks (1) moves (moving right) outside rapidly under the positive pressure effect, slide blocks drive valve pocket (8) moves to right and reaches certain position, two months v notch vs on the spool (7) are covered, at this moment, back pressure chamber (16) is closed, slide blocks rests on the new position, the oil hydraulic motor load is heavy more, the pressure that is reflected in oil input channel (14) lining is high more, left side annular chamber gives the active force of spool (7) and stage clip (10) big more, and the position that slide blocks moves to right is also big more, and the driving torque of motor promptly improves fast with the increase of discharge capacity and pressure, otherwise load alleviates, oil pressure reduces, and spool (7) moves to left under the effect of balance spring, and pressure oil is through left annular chamber, spool moon v notch v (11), oil inlet and oil return road (12), all press oil duct (13) to enter back pressure chamber (16).At this moment, slide blocks (1) moves to left, and motor displacement reduces, and rotating speed improves.The action of variable displacement pump is opposite fully, and pressure raises, the back pressure chamber oil-feed, and slide blocks moves to left, and pump displacement reduces, and pressure reduces, the back pressure chamber oil return, slide blocks moves to right, and pump displacement strengthens.On the housing of pump and motor, all be equipped with and adjust sieve bolt (not drawing among the figure),, the folding of the slide blocks on both sides is moved reach substantially synchronously, and can adjust pump and motor on a fixing characteristic curve in order to adjust the balance spring of servo valve.
Be the running principle of variable displacement motor under other operating mode below.
A, reversing
As oil hydraulic motor, be to need reversing mostly, can reverse as motor among Fig. 1, but reversing can not variable, its principle is seen Fig. 2, during the motor reversing, former return opening becomes filler opening, and low pressure back oil road (15) changes the high pressure oil input channel into, the right annular chamber pressurized of servo valve, the valve Job's tears is moved to the left under hydraulic coupling and balance spring pressure, and the moon v notch v (11) on the spool is linked up with oil duct (14).At this moment, the fluid of back pressure chamber (16) all flows into back oil road under the positive pressure of slide blocks (1), slide blocks (1) is in the maximum position that moves to right, the motor displacement maximum, moment of torsion is also maximum, but rotating speed is the slowest, reversing does not require that the motor of speed change is suitable in many instances, the wheel motor of hydralic drive automobile particularly, hydraulic ransaxle or hydraulic gearbox are the most suitable, in reversing need be come to nothing the crane tool or ship deck machinery of (freewheel state), this type of motor also can be competent at, and requires the machinery of speed change can use the four effect oil motors of Fig. 4 in reversing.
B, slide
Need slide as the wheel oil hydraulic motor, can save a lot of fuel because slide.Fig. 1, Fig. 4, oil motor shown in Figure 5 all can be accomplished this point, no matter advance to change or reversing, as long as slide blocks front pressurized reduces to a certain degree, being contained in slide blocks return spring (accompanying drawing does not draw) and balance spring behind has enough thrust to push slide blocks to rotor direction, make motor be in minimum displacement position, promptly be in the freewheel state substantially.
C, reversing speed change
The size and the position of appropriate change back pressure chamber (16), see Fig. 4, just can realize the reversing variable of oil hydraulic motor, but can produce the static pressure imbalance of slide blocks, aggravate the wearing and tearing of each rubbing surface, if on these rubbing surfaces, add needle bearing, certainly will increase the complexity of motor structure, and destroy the sealing of back pressure chamber, therefore except that multiaction low-speed big oil motor, the double-action motor had better not reverse variable, can adopt reversing gear (mechanical commutation) on fixed hydraulic equipment.
D, braking
As long as housing, rotor, blade, the rigidity of live axle, the Intensity Design of sliding-vane motor are reasonable, motor of the present invention can directly be used for braking fully, the method of oil inlet and oil return valve is closed in employing, automobile or machinery are shut down rapidly, no matter advance car or reversing, all close oil input channel or back oil road by the control valve that is contained on the motor during braking, the high pressure that the motor inner chamber forms will reach 2-3 times of maximum normal pressure, and motor can be in displacement automatically during braking.
Five, T-shaped blade (19)
Its epitrochanterian blade of vane pump or sliding-vane motor is many more, flow or moment of torsion are equal more, performance is good more, but blade is many, the intensity of rotor and blade itself has just become problem, as the sliding-vane motor that requires band brake to stop, this problem is especially outstanding, and its way can only be bulged blading and reduce the sheet number, and improve material, because of the application of these three ways all is subjected to certain limitation, so the present invention takes to increase the way of paying blade, has increased a pair blade in oil hydraulic motor, its primary blades can reduce, can reach like this and both thicken primary blades, do not weaken the purpose of rotor strength again, increased a pair blade, the short radius circular arc on the sliding seat can shorten, for multiaction sliding-vane motor particular importance, it is quite favourable to use flow groove balancing method for root of blade.The T-shaped blade inserts in the epitrochanterian groove, and its cross head is clipped in the groove circular hole, can only do a spot of moving radially, and cross head is not dropped out groove when guaranteeing the blade high speed rotating.
Six, multiaction variable vane motor
Structural principle according to double-function variable vane pump and motor can directly be made multi-function variable vane pump and motor.What its practical value was bigger is the multiaction variable vane motor.Fig. 4 is four actuation variable blade structure schematic diagrams, use the main blade structure of paying, primary blades (18) plays sealing and produces torque, pay blade (19) and only play sealing and isolate the high low pressure chamber, transition plate (3) and short radius circular arc are made integral body becomes anchor shape piece (21), and anchor shape piece embeds in the groove of housing (22), just maintain static, slide blocks (1) sipes direct and housing is formed back pressure chamber (16), and sipes should have the certain depth ratio, otherwise slide blocks is stuck easily.4 servo valves (4) are contained in the inside of 4 slide blockss (1) respectively.Servo valve can be a rotary valve, also can be slide-valve, reaches synchronous adjustment by the connecting rod on the motor end cap, oil cylinder, spring mechanism.
Architectural overview:
One, the decomposition of stator circle
4 curves of double-action variable pump stator circle inwall can resolve into 4 blocks at least: be respectively 2 of the blocks of semi major axis circular arc, the short radius circular arc comprises 2 of the blocks of transition curve.If the block of transition curve is separated from short radius circular arc block again, then the block sum has increased by 4 again, is total up to 8.If every transition curve is served as by two transition plates respectively, then 4 transition curves are served as by 8 transition plates, the block that this moment, double-acting vane pump stator circle was divided into has 12, Fig. 1, Fig. 5 are this kind structures, Fig. 4 is four actuation variable sliding-vane motor structural drawing, in this structure, the block of short radius circular arc and 4 transition plates are made integral body, help processing, assembling and simplified construction.What of block variable displacement pump stator circle resolve into, and are relevant with processing technology, irrelevant with the parameter of pump.
Two, the formation of back pressure chamber
A, by the behind excrescence of slide blocks directly and the inner walls of pump form back pressure chamber, this kind method is simple in structure, easy to manufacture, the back pressure chamber hydraulic coupling acts directly on the slide blocks, back pressure chamber can be an open type, also can be enclosed, uses the back pressure chamber of open type, the slide blocks front is basic identical with the mean value of the active force area at the back side, and back pressure chamber has damping hole to be communicated with the positive pressure chamber.This structure back pressure chamber does not require sealing.Use the enclosed back pressure chamber and require high-seal, servo valve or other control valve are only passed through in the turnover of back pressure chamber fluid, and the back pressure area is more a lot of greatly than malleation area.
B, according to the size of variable displacement pump rotor axial and warp-wise dimension scale, use circle or square piston and pump case and form back pressure chamber, the pressure of piston acts on earlier on the holder iron, pass to slide blocks by holder iron again, bear the static pressure imbalance by holder iron and piston, holder iron and piston can be made integral body, also can separate, this structure can be made the double-action oil motor of bidirectional variable, and its shortcoming is that radial dimension is bigger, and overall weight and volume are all bigger.
Three, control mode
Double-action and multi-function variable vane pump and motor rely on the folding of slide blocks to move, and reach the purpose of variable, and the active force that the slide blocks folding is moved is from following several forms:
A, armstrong's patent controlling type
In this in mode, the active force of hand by connecting rod, lever, crank arm or eccentric wheel promotes slide blocks and moves do folding, the folding of slide blocks is moved has synchronous effect.
B, automatic oil cylinder, mechanically controlled type
This mode is equipped with balance spring by single oil cylinder, and by lever, crank arm or eccentric wheel promotes each slide blocks and moves do folding, the pressure of system averages out by oil cylinder and spring, and the folding of each slide blocks is moved has synchronous effect.
C, pressure spring controlling type
The positive stress surface product moment with the back side of slide blocks is determining pressure difference, the compression degree of this pressure difference and balance spring, determining the folding position of slide blocks, just determining the discharge capacity of pump or motor, the back pressure lifting surface area of slide blocks and malleation lifting surface area are made certain difference, add the adjusting of balance spring can control pump and motor on specific power curve, the method is the simplest, but limited by the strictness of speed range, be applicable to the motor of constant rotational speed supporting, the centrifugal force difference of blade is very big during because of high and low rotating speed, area difference is fixed, and the elastic force of cluster spring is also fixed, and powerful centrifugal force will produce extra thrust to slide blocks, make pump and motor depart from original power curve, cause out of control.
D, servo valve controlling type
The control mode of servo valve has two kinds, first kind is outer active force controlling type, adopt multiple modes such as manual, centrifugal, vacuum, proportion electro-magnet, feedback oil cylinder to control moving of servo valve, moving of each valve of this kind mode reaches synchronously easily, and second kind is interior active force controlling type, with the pressure of pump or motor self, the pressure difference that on servo valve, causes, the drive servo valve moves, and can reach the same moved further of slide blocks substantially by the adjustment spring, sees Fig. 2.Servo valve can be contained on the slide blocks, also can be contained on the housing, uses servo valve, and the seal request of back pressure chamber is strict, otherwise can cause interior leakage, reduces volumetric efficiency.Use servo valve, the influence that the powerful centrifugal force that blade was produced when pump and horse crossed high speed rotating moves for the folding of slide blocks is very little, and enough big back pressure will make pump variable free characteristic stable.
Same with the single action variable vane pump, the characteristic curve of double-action and multi-function variable vane pump and motor still can be designed to various control forms such as pressure control, flow control, power control, rotating speed control as requested.Originally the equipment of application single action variable pump and double-action metering pump, machinery, vehicle etc. all can be replaced by double-function variable vane pump.

Claims (5)

1, a kind of multiaction variable vane motor, it includes main shaft, the pump housing, be arranged in the stator of housing, be installed in the rotor on the main shaft, several radial grooves are arranged on the rotor, one group of blade is contained in the radial groove slidably, feature of the present invention is: the stator that is arranged in housing (6) is the slide blocks (1) that has the semi major axis circular arc camber by two, two sliding seats (2) with short radius circular arc camber, eight transition plates (3) with transition curve curved surface are formed, two slide blockss (1) rotation that shape is identical is symmetrically placed in the left and right sides that housing (6) lining is positioned at rotor, two sliding seats (2) rotation that shape is identical is symmetrically fixed on housing (6) inwall and is positioned at rotor both sides up and down, the two ends up and down of two slide blockss (1) are close to and can do the folding of change motor displacement respectively and move on sliding seat with the two ends, the left and right sides of two sliding seats (2), eight transition plates (3) are set on the dovetail groove of short radius circular arc camber the right and left of two sliding seats (2).
2, multiaction variable vane motor according to claim 1, it is characterized in that: the front of slide blocks (1), one side towards rotor is the curved surface of a circular arc or curve, slide blocks (1) last protuberance behind is attached on the step of housing (6) inwall, the following protuberance at slide blocks (1) back side is close to an end of lower slider seat, up and down protuberance directly with housing (6) composition back pressure chamber (16), the corner of protuberance has groove up and down, blade or Stamping Steel Ribbon are housed in the groove, in order to guarantee the sealing of back pressure chamber, the intermediate portion of following protuberance is equipped with the servo valve (4) of controlled variable and is drilled with into oil drain passage (14), (15), the most advanced and sophisticated up and down position of slide blocks (1) is milled with four breach (5) of position symmetry, two slide blockss have eight breach, run into eight transition plates (3) when avoiding the slide blocks folding to slide.
3, multiaction variable vane motor according to claim 1, it is characterized in that: the middle upper portion of sliding seat (2) is a convex, the convex surface is a circular arc concave surface, the radius of the circular arc camber of sliding seat (2) be slightly larger than rotor radius and and rotor concentric, the convex both sides are milled with dovetail groove and are used for the transition plate (3) that suit has dovetail mount.
4, multiaction variable vane motor according to claim 1, it is characterized in that: transition plate (3) is sleeved on the sliding seat (2) with dovetail mount, be movable assembling type, the wearing and tearing back is replaceable, short radius circular arc on one end of transition plate (3) curved surface and adjacent sliding seat (2) convex joins, the semi major axis circular arc of the other end of curved surface and adjacent slide blocks (1) or curve and surface intersect, and its intersection point changes with the slip of slide blocks.
5, multiaction variable vane motor according to claim 1 is characterized in that described structure can be made into multi-function variable vane pump.
CN 92102268 1992-04-07 1992-04-07 Multi-action variable vane pump and motor Expired - Fee Related CN1036088C (en)

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Application Number Priority Date Filing Date Title
CN 92102268 CN1036088C (en) 1992-04-07 1992-04-07 Multi-action variable vane pump and motor

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Application Number Priority Date Filing Date Title
CN 92102268 CN1036088C (en) 1992-04-07 1992-04-07 Multi-action variable vane pump and motor

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CN1036088C true CN1036088C (en) 1997-10-08

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN100462584C (en) * 2004-07-30 2009-02-18 Vhit公司 Coupling

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CN201396276Y (en) * 2009-04-28 2010-02-03 武振芳 Hydraulic vane motor
CN104791246A (en) * 2015-04-06 2015-07-22 山东交通学院 Pinion-and-rack double-acting blade type secondary assembly
CN105386970A (en) * 2015-10-21 2016-03-09 何家密 Seal for fit of inlet and outlet in two sides of displacement blade pump, blades and pump interior
JP6769068B2 (en) * 2016-03-28 2020-10-14 株式会社ジェイテクト Vane pump
DE102017201213A1 (en) * 2017-01-26 2018-07-26 Volkswagen Aktiengesellschaft Vane pump

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN100462584C (en) * 2004-07-30 2009-02-18 Vhit公司 Coupling

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