JP2006291920A - Piston pump - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a piston pump wherein working of a casing is facilitated, rigidity is not required, the number of components can be reduced, noise is restrained, and operation can be easily confirmed before attachment of the casing. <P>SOLUTION: This piston pump is provided with a swash plate 3, a cylinder block 4 equipped with a plurality of pistons 36 sliding with the swash plate 3, a plate front cover 1 to which a swash holder 2 having a pintle 10 pivotally supporting the swash plate 3 is attached, and the casing 5 housing a swash holder 2 having the pintle 10 together with the front cover 1. A drive shaft 6 rotationally driving the cylinder block 4 is inserted by the front cover 1. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a swash plate type variable displacement piston pump.

  A conventional piston pump of this type (see, for example, Patent Document 1) includes a swash plate 200 that is a swash plate, and a plurality of pistons that slidably contact the swash plate 200 and discharge fluid by rotating with respect to the swash plate 200. A cylinder block 202 having 201 and a pintle 203 that is a shaft that variably supports the tilt angle of the swash plate 200 are provided, and the pintle 203 is attached to the through hole of the case 204.

205 is a drive shaft that is connected to a motor (not shown) and rotates the cylinder block 202, 206 is a discharge port, 207 is a suction port, 208 is a spring that tilts and biases the swash plate 200, and 209 The discharge amount adjusting screw 210 for adjusting the tilt angle of the swash plate 200 is also a discharge pressure adjusting screw.
JP 59-60083

  In the conventional piston pump, since the pintle 203 is attached through the case 204, a hole must be formed in the side surface of the case 204, and packings that prevent oil in the case 204 from leaking are required. . In order to support the pintle 203, it is necessary to make the case 204 rigid using iron or the like.

  When vibration transmitted from the cylinder block 202 to the swash plate 200 is transmitted to the pintle 203, noise is generated outside the case 204.

  Since the swash plate 200 is held by the pintle 203, it is necessary to check the operation of the swash plate 200 after being installed in the case 204. Since the operation cannot be checked with the case 204 removed, the assembling workability is poor.

  Further, since the swash plate 200 is moved by the secondary force adjusted by the discharge amount adjusting screw 209 or the secondary pressure adjusted by the pressure adjusting screw 210 to change the flow rate, an extra valve or the like is required. Since an external device such as an electric motor that drives the pintle 203 to move the swash plate 200 is required, the structure becomes complicated.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a piston pump in which case processing is simplified, rigidity is not required, the number of parts can be reduced, noise can be suppressed, and operation can be easily confirmed before attaching the case. It is.

  A piston pump according to the present invention includes a swash plate, a cylinder block having a plurality of pistons whose tips are in sliding contact with the swash plate, and reciprocating as the piston rotates along the swash plate, and the swash plate A base having an axis that pivotally supports the swash plate so that an inclination angle can be changed; and a case that forms an outer shell together with the base and accommodates the swash plate and the cylinder block that are pivotally supported by the axis. The outer shell is formed with an insertion hole through which a drive shaft for rotationally driving the cylinder block is inserted.

  In the above configuration, the shaft is held by a swash holder, the swash holder is attached to the base body, and the drive shaft passes through the base body, the swash holder and the swash plate and is coupled to the cylinder block.

  In the above configuration, the swash holder includes a first stopper that locks the swash plate at a maximum inclination angle, a spring that presses the swash plate toward the first stopper, and the swash plate. Is pushed by the piston against the spring, and the swash plate has a second stopper that locks at an angle that makes a minimum inclination angle.

  In the above configuration, the base body is a front cover that is attached to a front end portion of a drive unit having the drive shaft and has an insertion hole through which the drive shaft is inserted, and the case includes a cylindrical body having one end attached to the front cover. And an end cover for closing the other end of the cylindrical body.

  According to the piston pump of the present invention, since the shaft is held by the swash holder of the front cover and the shaft is covered with the case, packing for preventing oil leakage caused by attaching the shaft to the hole of the case as in the prior art is provided. This is unnecessary and the number of parts can be reduced. The vibration from the cylinder block can be confined in the case, and the noise caused by the shaft being exposed to the outside and the noise caused by the case vibration caused by the vibration transmitted from the shaft to the case can be reduced. In addition, hole processing for attaching the case shaft is not required, and the structure of the case is simplified and processing is facilitated. Since no load is applied to the case by the shaft, there is no need to increase the rigidity of the case. Further, since the swash plate is held on the shaft of the swash holder of the base body, the operation of the swash plate can be confirmed before the case is put on, so that the assembly workability is good.

  Also, if the swash plate is supported in an inclined state by a spring, and the swash plate is moved to a small inclination angle against the spring by a pressing force from a piston above a certain level, an extra valve or the like is unnecessary compared to the conventional part. The number of points can be reduced and the structure becomes simple. Further, for example, the motor torque for driving the drive shaft by rotating the swash plate to an angle with a small inclination angle can be reduced, and the motor capacity can be reduced.

  A piston pump according to an embodiment of the present invention will be described with reference to FIGS. That is, this piston pump holds the swash plate 3 which becomes a swash plate through the pintle 10 which becomes an axis | shaft in the swash holder 2, makes the cylinder block 4 slide-contact with the front surface of the swash plate 3, and those whole are cylindrical. Covered with case 5 or the like. The case 5 includes a cylindrical body 50 that surrounds the swash plate 3 and the cylinder block 4, and an end cover 51 that closes an end of the cylindrical body 50, and is attached to the front cover 1 to which the swash holder 2 is attached.

  First, the front cover 1 has an insertion hole (not shown) through which the drive shaft 6 is inserted, and is attached to, for example, a front end portion of an electric motor (not shown) having the drive shaft 6.

  The swash holder 2 has a U-shape, an insertion hole 9 through which the drive shaft 6 is inserted is formed in the central piece 7, and a hole 52 for projecting the pintle 10 in the opposite direction is formed at the tip of both end pieces 8. Yes. The base of the pintle 10 passed through the hole 52 abuts against the outer surface of the both end pieces 8 and is attached to the both end pieces 8 by two screws 11. Further, a seating surface 13 serving as a stopper for supporting the swash plate 3 from a posture perpendicular to the axial direction of the drive shaft 6 to a maximum tilt angle (maximum tilt angle), for example, 15 degrees is projected on one side of the central piece 7. A stopper 14 that supports the swash plate 3 at a minimum inclination angle (minimum inclination angle), for example, 4.5 degrees, protrudes larger than the seat surface 13 on the side. A spring receiving portion 15 is formed in the vicinity of the stopper 14. The central piece 7 is attached to the front cover 1 with an attachment such as a screw in a state where a swash plate 3 described later is attached or before the swash plate 3 is attached.

  The swash plate 3 is provided with a thrust plate 16 on the front surface, a plurality of shoes 17 are slidably contacted with the thrust plate 16, the shoes 17 are passed through a plurality of holes of the retainer plate 18, and the shoes 17 are pressed against the thrust plate 16 by the retainer plate 18. The retainer plate 18 is pressed by a retainer guide 38 to be described later. Each shoe 17 has a spherical recess 31 formed on the surface. The swash plate 3 and the thrust plate 16 respectively have insertion holes 23 and 24 through which the drive shaft 6 passes. The retainer plate 18 also has a recess 19 at the center for receiving the retainer guide 38 that also serves as the insertion of the drive shaft 6. On the other hand, the bearing portion 20 protrudes from the swash plate 3 at the periphery of the swash plate 3 so as to face both end pieces 8, and the pintle 10 is pivotally supported in the shaft hole 21 of the bearing portion 20. As a result, the swash plate 3 can be rotated around the pintle 10, and one side of the back surface of the swash plate 3 abuts against the seat surface 13 at a position inclined 15 degrees from a posture perpendicular to the axial direction. The other side portion of the back surface is locked to the stopper 14 at a tilt angle of 4.5 degrees, and the swash plate 3 can be rotated within a range where the seat surface 13 and the stopper 14 are in contact with each other. Further, a spherical spring receiving recess 25 is formed on the back surface of the swash plate so as to face the spring receiving portion 15 of the swash holder 2, and a spring seat 26 having a hemispherical surface is brought into contact with the spring receiving recess 25. A swash plate 3 is pressed against the seat surface 13 by compressing and interposing a spring 27 using a coil spring between the receiving portion 15 and the receiving portion 15.

  The cylinder block 4 passes through a hole 34 through which the drive shaft 6 passes in the center, and a coupling portion 32 with the drive shaft 6 by, for example, a spline is formed at an end portion of the hole 34 close to the swash plate 3, and a compression coil spring is formed in the remaining space. The spring 33 using is stored. A plurality of cylinder portions 35 having openings around the holes 34 of the cylinder block 4 facing the swash plate 3 are formed in parallel to the holes 34, the pistons 36 are accommodated in the respective cylinder portions 35, and a head portion 37 at the tip of the piston 36. Is formed into a spherical surface, and the head 37 protrudes toward the swash plate 3. The tip of the piston 36 is slidably fitted into the spherical recess 31 of the shoe 17 held by the swash plate 3 and is sphere-coupled so as to prevent it from coming off. Also, the retainer guide 38 is accommodated across the coupling portion 32 of the hole 34, the rear end is pushed by the spring 33, the front end is slidably fitted into the recess 19 of the retainer plate 18, and the retainer plate 18 is inserted into the thrust plate. 16 is pressed down. The retainer guide 38 includes a ring 40 that is pressed against one end of the spring 33, a guide ring 41 that has a partial spherical surface that is in sliding contact with the recess 19, and a plurality of connecting rods that connect the ring 40 and the guide ring 41 to each other. The connecting rod 42 is slidably inserted into a groove formed in the coupling portion 32 so that the coupling between the drive shaft 6 and the coupling portion 32 is not hindered.

  A valve plate 45 is slidably disposed at the end of the cylinder block 4 opposite to the swash plate 3. The valve plate 45 has a discharge groove 55 and a suction groove 56, and a communication hole 57 is formed at the end of each cylinder portion 35 so that these cylinder portions 35 communicate with each other according to the rotation of the cylinder block 4. Has been. A center of the valve plate 45 has a hole 46 that penetrates the drive shaft 6, and a bearing 47 is disposed outside the hole 46. Reference numeral 48 denotes a positioning portion using positioning pins.

  The drive shaft 6 is passed through the cylinder block 4 through the holes 23, 24, 19 and 34, and is coupled by the coupling portion 32 to hold the cylinder block 4, and the tip of the drive shaft 6 is pivotally supported by the bearing portion 47. For this reason, the cylinder block 4 can be rotated by the rotation of the drive shaft 6.

  The cylindrical body 50 and the front cover 1 of the case 5 are made of, for example, aluminum which is a good heat conductor and can be easily processed, and the cylindrical body 50 is extruded. Further, heat radiation irregularities 56 are formed on the peripheral surfaces of the front cover 1 and the cylindrical body 50. One end of the cylinder 50 is attached to the front cover 1, and the end cover 51 is attached to the other end of the cylinder 50 to close the inside of the cylinder 50. A positioning recess (not shown) for fitting the positioning portion 48 is formed on the inner surface of the end cover 51, a recess (not shown) for receiving the bearing portion 47 is formed, and the suction groove 56 of the valve plate 45 is formed. A hole 58 serving as a fluid inflow port communicating with the discharge groove 55 and a hole 59 serving as a discharge port are formed.

  The front cover 1, the cylindrical body 50, and the end cover 51 are connected to each other through a connecting hole 60 with a common connecting tool such as a bolt, and are attached to a front end portion of an electric motor (not shown) with a common connecting tool through a connecting and mounting hole 61. ing. In order to fill the case 5 with oil, a liquid-tight member such as a packing (see FIG. 5) is formed between the front cover 1 and the cylinder 50, between the cylinder 50 and the end cover 51, and between the insertion hole of the front cover 1 and the drive shaft 6. Not shown).

  The operation of this piston pump will be described. As the cylinder block 4 rotates, the piston 36 moves along the thrust plate 16 of the swash plate 3 via the shoe 17, thereby causing the piston 36 to reciprocate within the cylinder block 4, and thereby the fluid in the cylinder portion 35. For example, exhale or inhale oil. That is, the fluid is pushed out from the cylinder portion 35 where the piston 36 moves backward into the discharge groove 55 of the valve plate 45, and the fluid is sucked into the cylinder portion 35 where the piston 36 moves forward from the suction groove 56 of the valve plate 45. When the pressure in the cylinder block 4 rises to a certain set value during the process of discharging oil, a force that pushes the piston 36 toward the swash plate 3 is generated. When the force becomes larger than the force of the spring 27 attached to the back of the swash plate 3, the swash plate 3 starts to move with the pintle 10 as a fulcrum and finally stops against the stopper 14. By this action, the tilt angle of the swash plate 3 is reduced, so that the stroke of the piston 36 is shortened, and the amount of oil discharged is reduced from the state before the swash plate 3 moves. On the other hand, before the swash plate 3 moves, the swash plate 3 is pushed toward the piston 36 by the force of the spring 27 attached to the back of the swash plate 3 while the pressure until the set pressure is reached is low. In this case, the amount of rotation with the pintle 10 as a fulcrum is regulated by the swash plate 3 being locked to the seating surface 13, so the positional relationship is determined. That is, the maximum tilt angle of the swash plate 3 is determined and becomes the maximum value of the displacement capacity.

  Therefore, when a load is connected to the inflow port and the discharge port, the pressure fluid can be supplied to the load. When the load increases and the pressure of the pressurized fluid increases, the force by which the piston 36 pushes the swash plate 3 increases accordingly. When the spring 27 overcomes the spring 27, the swash plate 3 rotates and the tilt angle decreases, and the stopper 14 is engaged. Therefore, the reciprocating distance of the piston 36 is shortened, the amount of fluid pushed out is reduced, and the burden on the cylinder block 4 is reduced.

  According to this embodiment, since the pintle 10 is supported by the front cover 1 and the pintle 10 is covered with the case 5, packing for preventing oil leakage due to the pintle 10 being attached to the case 5 as in the past is provided. This is unnecessary and the number of parts can be reduced.

  The vibration from the cylinder block 4 can be confined in the case 5, and the noise caused by the pintle 10 being exposed to the outside and the noise caused by the vibration of the pintle 10 being directly transmitted to the case can be reduced as in the prior art. it can. Furthermore, noise reduction can be achieved by inserting a damping steel plate between the swash holder 2 and the front cover 1.

  Moreover, the hole processing for attaching the pintle 10 of the case 5 is not required, the structure of the case 5 is simplified, and the case processing is simplified. In this case, since the cylinder 50 does not ask | require rigidity, the material selection in consideration of workability and heat dissipation, such as extrusion molding using aluminum, for example, becomes easy.

  Further, since the swash plate 3 is held on the pintle 10 of the front cover 1, the swash plate 3 is moved before covering the case 5 to check the operation of the swash plate 3, and the drive shaft 6 is inserted into the front cover 1 through-hole, swash holder. 2 can be inserted into the insertion hole 9 and the hole 23 of the swash plate 3 and the operation of the swash plate 3 can be confirmed, and the operation can be confirmed while adjusting the positional relationship between the swash plate 3 and the drive shaft 6. Good assembly workability.

  In addition, since the swash plate 3 is supported by the spring 27 and the swash plate 3 is moved by the pressing force from the piston 36 to change the flow rate, the secondary pressure and the secondary force as in the prior art are not required, thus saving energy. This eliminates the need for extra equipment such as extra valves and electric motors, reduces the number of parts, and simplifies the structure. Further, when a load is applied to the piston pump, the swash plate 3 is moved to the minimum tilt angle, so that the motor torque for driving the drive shaft 6 is reduced, and the motor capacity can be reduced, saving energy.

  In the present invention, the drive shaft 6 can be inserted from the end cover 51 side.

It is a perspective view in the state where a case of one embodiment of this invention was removed. It is a perspective view before attaching a front cover. It is the side view. FIG. 3 is a bottom view of FIG. 2. FIG. 4 is a sectional view taken along line AA in FIG. 3. FIG. 4 is a sectional view taken along line BB in FIG. 3. It is CC sectional view taken on the line of FIG. It is an AA line sectional view when a big load is applied. It is a BB line sectional view when a big load is applied. It is a perspective view of the state which attached the front cover and the cylinder. It is a perspective view of the state where the end cover was attached. It is sectional drawing of a prior art example. It is a perspective view of a prior art example.

Explanation of symbols

1 Front cover
2 Swash holder 3 Swash plate 4 Cylinder block 5 Case 6 Drive shaft 9 Insertion hole 10 Pintle (shaft)
13 Seat (first stopper)
14 Stopper 27 Spring 36 Piston 50 Cylindrical body 51 End cover

Claims (4)

  A swash plate, a cylinder block having a plurality of pistons whose tips are in sliding contact with the swash plate, and a reciprocating motion of the piston along the swash plate; and an inclination angle of the swash plate can be changed. A base body having a shaft for pivotally supporting the swash plate, and a case for forming an outer shell together with the base body and housing the swash plate and the cylinder block pivotally supported by the shaft, and rotating the cylinder block A piston pump in which an insertion hole for inserting a drive shaft is formed in the outer shell.   2. The piston pump according to claim 1, wherein the shaft is held by a swash holder, the swash holder is attached to the base body, and the drive shaft passes through the base body, the swash holder and the swash plate and is coupled to the cylinder block. .   The swash holder includes a first stopper that locks the swash plate at a maximum inclination angle, a spring that presses the swash plate toward the first stopper, and the swash plate is moved by the piston. The piston pump according to claim 2, further comprising a second stopper that locks the swash plate at an angle that forms a minimum inclination angle when pushed against the spring.   The base is a front cover attached to a front end portion of a driving means having the drive shaft and having an insertion hole through which the drive shaft is inserted, and the case has a cylindrical body whose one end is attached to the front cover, and the cylindrical body The piston pump according to claim 3, comprising an end cover that closes the other end of the piston pump.

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