JP2000154775A - Piston pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a multiple pump combining a variable displacement piston pump with a fixed displacement pump capable of miniaturizing a pump whole body, reducing the number of parts and easy to assemble. SOLUTION: A fixed pump side cylinder 8 is opened to a stepped part (upper surface 6A of fixed pump part 6) formed on a cylinder block 3, and a projected end side of a fixed pump side piston 11 stored in the fixed pump side cylinder 8 is made contact with a fixed cam plate 15 arranged on an outer periphery of a variable pump part 5 of the cylinder block 3. A variable pump side piston 10 is stored in a variable pump side cylinder 7 opened to an upper surface 5A of the variable pump part 5 of the cylinder block 3, and an inclined angle of a variable cam plate 13 with which the projected end side of the variable pump side piston 10 makes contact is controlled by an inclined angle control means.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement of a multiple piston pump in which a fixed displacement pump is added to a variable displacement piston pump.

[0002]

2. Description of the Related Art Heretofore, as a hydraulic pump for a construction machine, for example, a hydraulic pump having a variable capacity swash plate type piston pump of a multiple type has been known. In such a multiple swash plate type piston pump, a plurality of systems (for example, two systems) in which the kidney ports are arranged concentrically with different diameters are provided for a plurality of pistons arranged on a concentric circle. In addition, suction and discharge are performed as different pumps for each system.

FIG. 6 shows a triple pump in which a gear pump 110 having a fixed capacity is added to such a double swash plate type axial piston pump 100.

[0004] As shown in the figure, a pump shaft 101 of a swash plate type axial piston pump 100 has a drive shaft 10.
2 is supported. The cylinder block 103 accommodated in the pump case 101 is spline-coupled to the drive shaft 102, and is rotatable with the drive shaft 102. The drive shaft 102 is rotatably driven at a projecting end from the pump case 101 by a drive motor (not shown).

On the upper surface of the cylinder block 103, a plurality of cylinders 104 are opened on a piston pitch circle centered on the drive shaft 102, and a piston 105 is slidably accommodated in each cylinder 104. On the other hand, a valve plate 106 is in contact with the bottom surface of the cylinder block 103, and this valve plate 10
A suction port and a discharge port kidney port are formed in 6. In this case, the suction-side and discharge-side kidney ports are formed in two layers on the inner side and outer side, respectively, and each piston cylinder selectively communicates with the outer side kidney port or the inner side kidney port.

A swash plate 107 whose tilting angle can be changed is disposed opposite to the upper surface of the cylinder block 103, and the protruding end of the piston 105 contacts the swash plate via a piston shoe 108. As a result, when the cylinder block 103 rotates, the inside of the cylinder 104 is expanded and contracted by the piston 105, and suction of hydraulic oil from the suction-side kidney port and discharge of hydraulic oil to the discharge-side kidney port are performed.

The pump case 101 has a gear pump 110
Is fixed. The drive shaft 111 of the gear pump 110
Is connected to the drive shaft 102 that penetrates the cylinder block 103. Thus, the gear pump 110 is driven in synchronization with the piston pump 100.

The discharge pressure from the gear pump 110 is guided to the piston pump 100 through an oil guiding bush 112 provided between the gear pump 110 and the piston pump 100. The tilt angle of the swash plate 107 of the piston pump 100 is feedback-controlled based on the discharge pressure from the piston pump 100 and the discharge pressure from the gear pump 110, so that the entire multiple pump (that is, the piston pump 100 which is a variable pump, Gear pump 1 as a fixed pump
The constant horsepower control is performed for all the outputs (10 overall).

[0009]

However, in such a multiple pump as shown in FIG. 6, since the gear pump 110 is disposed on the extension of the drive shaft 102 of the piston pump 100, the overall length of the pump becomes longer. .

Further, since it is necessary to seal the bush 112 for guiding the discharge pressure of the gear pump 110 to the piston pump 100 side, an O-ring 113 and the like are required, and the number of parts is increased.

Further, when assembling the gear pump 110 to the piston pump 100, it is necessary to assemble the bush 112 and the drive shaft 111 at the same time as assembling the spigot portion. Required.

The present invention has been made in view of such a problem, and in a multiple pump in which a fixed displacement pump is combined with a variable displacement piston pump, the entire pump can be reduced in size and the number of parts can be reduced. It is an object of the present invention to provide a device which can be easily assembled.

[0013]

According to a first aspect of the present invention, in a piston pump having a cylinder block housed in a pump case, a plurality of variable pump-side cylinders formed in the cylinder block are provided. A plurality of fixed pump-side cylinders formed on a piston pitch circle different from the variable pump-side cylinder, and a tilt angle at which the protruding end side of the variable pump-side piston housed in the variable pump-side cylinder comes into contact can be changed. A variable swash plate,
A tilt angle control means for controlling the tilt angle of the variable swash plate, and a fixed tilt angle fixed swash plate with which the protruding end side of the fixed pump side piston housed in the fixed pump side cylinder abuts.

According to a second aspect of the present invention, the fixed pump side cylinder is opened at a step portion of the cylinder block,
The fixed swash plate was disposed around the cylinder block.

According to a third aspect of the present invention, the fixed pump side piston is a shoeless shoe piston.

According to a fourth aspect of the present invention, the variable pump side cylinder and the fixed pump side cylinder can communicate with a common suction port.

[0017]

According to the first aspect of the present invention, when the piston pump is operated, hydraulic oil is discharged from the variable pump side cylinder and the fixed pump side cylinder, and the pump operates as a multiple pump. The control means controls the tilt angle of the variable swash plate based on the discharge pressure from the variable pump side cylinder and the discharge pressure from the fixed pump side cylinder,
For example, constant horsepower control of a piston pump is performed. in this case,
The discharge pressure guided from the fixed pump side cylinder to the tilt angle control means can be guided through an oil passage in the pump case, and a seal member or the like is not required as in the case where the fixed pump is mounted outside the pump case. The number of parts of the pump can be reduced. In addition, since the configuration acting as a variable pump and the configuration acting as a fixed pump of the pump are compactly assembled and housed integrally in the pump case, as in the case where the fixed pump is mounted on the drive shaft extension of the pump. The overall length of the pump is not lengthened, the pump can be miniaturized, and the pump can be easily manufactured because there is no need to mount the fixed pump from outside the pump case.

In the second invention, the fixed pump side cylinder is formed at the step of the cylinder block, and the fixed swash plate is disposed around the cylinder block. A compact configuration can be achieved, and the pump can be downsized.

In the third aspect of the present invention, since the fixed pump-side piston has no shoe, there is no possibility that the piston shoe interferes with the cylinder block, and the fixed pump-side piston can be arranged close to the cylinder block outer periphery. By reducing the diameter of the piston pitch circle of the fixed pump-side piston, the cylinder block can be downsized. Therefore,
The size of the pump can be further reduced.

In the fourth aspect of the present invention, the suction port is shared between the variable pump side cylinder and the fixed pump side cylinder, so that the suction pipe of the pump can be simplified.

[0021]

Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 shows a multiple pump according to an embodiment of the present invention.

As shown, the pump case 1 includes:
The drive shaft 2 is rotatably supported via a bearing. The drive shaft 2 is connected to a drive motor (not shown) at the protruding end 2A and is driven to rotate. A cylinder block 3 is housed inside the pump case 1, and the cylinder block 3 is spline-coupled to the drive shaft 2 at a drive shaft hole 4 formed through the cylinder block 3.
It is configured to be rotationally driven integrally with the drive shaft 2.

As shown in FIGS. 2 and 3, the cylinder block 3 includes a variable pump section 5 and a fixed pump section 6.
The variable pump portion 5 is an annular portion around the drive shaft hole 4, and a plurality of variable pump side cylinders 7 are opened on a predetermined piston pitch circle on the upper surface 5A. On the other hand, the fixed pump portion 6 is a portion in which the bottom surface 3A side of the cylinder block 3 is formed in a flange shape, and the upper surface 6A of the fixed pump portion 6 becomes a step portion in the cylinder block 3. A plurality of fixed pump-side cylinders 8 are opened on a predetermined piston pitch circle on the upper surface 6A. Variable pump side cylinder 7
A variable pump side piston 10 is slidably inserted, and a fixed pump side piston 8 is slidably inserted into the fixed pump side cylinder 8, respectively.

The bottom surface 3A of the cylinder block 3 contacts a valve plate 12 fixed to the pump case 1. On the valve plate 12,
Kidney ports (suction port and discharge port) on the variable pump side and the fixed pump side are respectively formed, each variable pump side cylinder 7 is provided on the variable pump side suction port or discharge port, and the fixed pump side cylinder 8 is provided on the fixed pump side. The suction port or the discharge port can be selectively connected in accordance with the rotation of the cylinder block 3, respectively.

The variable pump side kidney port is provided with a plurality of (for example, two) systems of suction ports and discharge ports arranged on different concentric circles so that each system operates as a different variable pump. You may.

Around the drive shaft 2, a cylinder block 3
Is provided with a variable swash plate 13 whose tilt angle can be changed. The variable swash plate 13 is disposed so as to face the upper surface 5A of the variable pump unit, and the protruding end of the variable pump side piston 10 abuts on the variable swash plate 13 via the piston shoe 14. Thus, when the cylinder block 3 rotates, the variable pump-side piston 10 expands and contracts, and the space in the variable pump-side cylinder 7 expands and contracts, whereby hydraulic oil is sucked from the variable pump-side suction port of the valve plate 3A. Hydraulic oil is discharged from the variable pump side discharge port.

In this case, the discharge amount from the variable pump side discharge port is determined according to the tilt angle of the variable swash plate 13. The tilt angle of the variable swash plate 13 is controlled by a tilt angle control (not shown). Controlled by means. This tilt angle control means includes:
The discharge pressure from the variable pump side discharge port and the discharge pressure from the fixed pump side discharge port are guided through an oil passage (not shown) formed inside the pump case 1.

On the outer periphery of the variable pump section 5 of the cylinder block 3, a fixed swash plate 15 with a fixed tilt angle is provided, and is fixed to the pump case 1. The fixed swash plate 15 faces the upper surface 6 </ b> A of the fixed pump portion, and the protruding end of the fixed pump-side piston 11 abuts via the piston shoe 16. As a result, when the cylinder block 3 rotates, the fixed pump-side cylinder 8 expands and contracts by means of the fixed pump-side piston 11 that expands and contracts.
The hydraulic oil is discharged to the fixed pump side discharge port.
Since the tilt angle of the fixed swash plate 15 is constant, the discharge amount from the fixed pump side discharge port is constant.

Next, the operation will be described.

When driving the multiple piston pump, the drive shaft 2 of the pump is rotated by the drive motor, and the cylinder block 3 is rotated. Thereby, the variable pump side piston 10 and the fixed pump side piston 1
1 expands and contracts the inside of the variable pump side cylinder 7 and the fixed pump side cylinder 8 to suck hydraulic oil from the variable pump side suction port and the fixed pump side suction port, and from the variable pump side discharge port and the fixed pump side discharge port. Is discharged. The hydraulic oil discharged from each system of the variable pump side discharge port and the discharge port of the fixed pump is supplied to various hydraulic devices.

In this case, the total output (discharge pressure × discharge amount) of the pump needs to be controlled to a predetermined constant horsepower (for example, a horsepower corresponding to the rated driving force of the drive motor). Therefore, the discharge pressure from the variable pump side discharge port and the fixed pump side discharge port is fed back to the tilt angle control means through an oil passage formed inside the pump case 1.
The tilt angle control means, based on these discharge pressures,
By changing the tilt angle of 4, the discharge amount from the variable pump side discharge port is controlled, and feedback control is performed so that the total output of the pump (the output of the entire variable pump and the fixed pump) is constant.

As described above, according to the multiple piston pump of the present invention, the discharge pressure from the fixed pump side discharge port is sent to the tilt angle control means through the oil passage inside the pump case 1, so that the fixed pump side No need for a bush or the like for conducting oil from
The number of parts can be reduced.

Further, in the multiple piston pump of the present invention, since one cylinder block 3 is provided with the variable pump section 5 and the fixed pump section 6, the structure acting as a variable pump and the structure acting as a fixed pump are compact. And housed in the pump case 1 integrally. Therefore, the size of the multiple piston pump can be reduced.

Further, in the multiple piston pump of the present invention, there is no need to assemble the fixed pump from the outside of the casing 1, so that complicated and troublesome assembling work is not required, and the pump can be easily manufactured.

FIGS. 4 and 5 show another embodiment of the present invention. This embodiment has a basic configuration shown in FIG.
Since the present embodiment is the same as the embodiment shown in FIG. 1, the following description will focus on differences from the piston pump of FIG.

In the piston pump of this embodiment, a fixed pump-side piston 21 without a shoe is employed instead of the fixed pump-side piston 11 and the piston shoe 16 of the embodiment shown in FIGS. By eliminating the piston shoe in this manner, the problem that the piston shoe interferes with the outer periphery of the variable pump section 5 of the cylinder block 3 is eliminated, so that the fixed pump side cylinder 8 can be formed closer to the variable pump section 5 side. Specifically, a concave portion 22 is formed on the outer periphery of the variable pump portion 5, and the fixed pump side cylinder 8 can be arranged close to the concave portion 22. Thus, the piston pitch circle radius of the fixed pump side cylinder 8 can be reduced, and the cylinder block 3 can be downsized, so that the pump can be further downsized.

In each of the above embodiments, the variable pump side suction port and the fixed pump side suction port are provided separately. However, the present invention is not limited to such an embodiment. The suction port and the suction port on the fixed pump side may be shared to form one suction port.
Further, in this case, the suction port of a pilot pump (for example, a trochoid pump) installed in the piston pump may be shared. By thus using a common suction pipe for the pump, the configuration of the pump can be simplified.

In each of the above embodiments, the piston pitch circle of the variable pump side cylinder 7 and the piston pitch circle of the fixed pump side cylinder 8 are each one. The piston pitch circles may be plural. In addition, not only the variable pump-side cylinder 7 but also the fixed pump-side cylinder 8 can be divided into a plurality of systems to function as a large number of pumps.

[Brief description of the drawings]

FIG. 1 is a sectional view of a piston pump showing an embodiment of the present invention.

FIG. 2 is a plan view of the same cylinder block.

FIG. 3 is a side view of the cylinder block.

FIG. 4 is a cross-sectional view of a piston pump showing another embodiment of the present invention.

FIG. 5 is a plan view of the cylinder block.

FIG. 6 is a sectional view showing a conventional multiple piston pump.

[Description of Signs] 1 Pump case 2 Drive shaft 3 Cylinder block 5 Variable pump section 6 Fixed pump section 7 Variable pump side cylinder 8 Fixed pump side cylinder 10 Variable pump side piston 11 Fixed pump side piston 12 Valve plate 13 Variable swash plate 15 Fixed swash plate 21 Fixed pump side piston 22 Recess

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 3H070 AA01 BB04 BB06 BB22 CC15 CC32 CC34 CC35 DD01 DD05 DD11 DD47 DD53 DD91 3H071 AA03 BB01 BB12 BB14 CC31 CC32 CC33 CC34 DD01 DD06 DD32

Claims (4)

[Claims] 1. A piston pump including a cylinder block housed in a pump case, wherein a plurality of variable pump-side cylinders formed in the cylinder block, and a piston pitch different from the variable pump-side cylinder of the cylinder block. A plurality of fixed pump-side cylinders formed on a circle; a variable swash plate having a variable tilt angle with which a protruding end of a variable pump-side piston housed in the variable pump-side cylinder comes into contact; A tilt angle control means for controlling the tilt angle; and a fixed tilt angle fixed swash plate with which the protruding end of the fixed pump side piston housed in the fixed pump side cylinder abuts. Piston pump. 2. The piston pump according to claim 1, wherein the fixed pump side cylinder is opened at a step portion of the cylinder block, and the fixed swash plate is disposed around the cylinder block. 3. The piston pump according to claim 2, wherein the fixed pump side piston is a piston without a shoe. 4. The piston pump according to claim 1, wherein said variable pump side cylinder and said fixed pump side cylinder can communicate with a common suction port.