JPH0643510Y2 - Tandem pump - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial field of application> The present invention is to insert a first cam ring, a first side plate, a second cam ring and a second side plate in this order into a hollow chamber of a pump housing, and The present invention relates to a tandem pump having a first rotor and a second rotor rotatably arranged in a second cam ring.

<Prior Art> The above-described tandem pump has the oil pressure acting on the surface of the first side plate 1 on the first rotor 2 side and the pressure of the second side plate 3 on the second rotor 4 side as shown in FIG. In order to oppose the pressure of the oil acting on the surface, the space between the end surface of the hollow chamber 5 on the second side plate 3 side and the second side plate 3 is divided into two spaces, that is, the first working chamber 6 and the second working chamber 7. The first side passage 3a is formed in the second side plate 3 to guide the pressure of the oil discharged from the second rotor 4 side to the first working chamber 6, and the first side plate 1, the second rotor 4, second
Elliptical hole 8 and pin 9 formed in the side plate 3
Through the second communication passage 3b formed of the communication passage portion 110 formed in the second side plate 3 and the gap passage portion 100 between the first
The pressure of the oil discharged from the rotor 2 side was guided to the second working chamber 7.

<Problems to be Solved by the Invention> In such a tandem pump, oil is removed from the gap between the first side plate 1, the second rotor 4, and the second side plate 3 in the gap passage portion 100 of the second communication passage 3b. A leak will occur. Also, since the cross-sectional area of this gap passage portion 100 is small,
Poor rise in the pressure of the oil introduced into the second action chamber 7 will occur.
If the gap passage portion 100 is enlarged to prevent this, the pump becomes large.

<Means for Solving Problems> The present invention has been made to solve the problems described above, and utilizes a communication hole provided in the pin as the second communication passage.

<Operation> The oil pressure on the second rotor side is guided to the first working chamber via the first communication passage, and the oil pressure on the first rotor side is formed in the communication hole formed in the pin and the second side plate. It is guided to the second working chamber via a second communication passage formed by the communication passage portion. This causes the second side plate to move to the first rotor and the second rotor.
It is pressed against the second rotor side according to the pressure of the oil generated from the rotor side.

<Embodiment> An embodiment of the present invention will be described below with reference to FIG. Reference numeral 10 is a first pump housing, 11 is a second pump housing, which are connected to the first pump housing 10 via bolts 12. First pump housing 10 and second pump housing 11
A hollow chamber 13 having a circular cross section is formed in the hollow chamber 13.
The first cam ring 20, the first side plate 21, the second cam ring 22, and the second side plate 23 are fitted in this order. A rotary shaft 24 is rotatably supported by the first pump housing 10 around the centers of the first cam ring 20 and the second cam ring 22, and the first rotor 25 is mounted on the rotary shaft 24 at a position corresponding to the first cam ring 20. The second rotor 26 is spline-engaged, and the second rotor 26 is spline-engaged at a position corresponding to the second cam ring 22. A plurality of vanes 27 are held on the first rotor 25 and the second rotor 26 so as to be slidable in the radial direction.
Further, inner peripheral cam surfaces 20a, 22a having an elliptical cross section in which one end of the vane 27 slides are formed on the inner peripheral surfaces of the first cam ring 20 and the second cam ring 22. A discharge port 21a and a suction port 21b are formed on the surface of the first side plate 21 on the first rotor 25 side, and the second side of the first side plate 21 is formed.
The surface on the rotor 26 side and the second rotor 26 of the second side plate 23
A discharge port 23a and a suction port 23b are formed on the side surface.

Two pins 30 are driven and fixed in parallel with the rotary shaft 24 in the first pump housing 10, and these pins 30 are connected to the first cam ring 20, the first side plate 21, the second cam ring 22, and the second side plate 23. Threaded through hole 31. Thereby, the first cam ring 20 and the second cam ring 22 are supported by the first pump housing 10 via the pins 30 in a phased state. The pin 30 has a pipe shape and has a circular communication hole 34 therein.

Further, a cylindrical first fitting portion 40 is formed on the end surface of the second pump housing 11 on the side of the second side plate 23, and the first fitting portion 40 on the side opposite to the second rotor 26 of the second side plate 23 is formed on the end surface thereof. Second fitting portion slidably fitted to the outer periphery of the fitting portion 40
41 is formed. The first fitting portion 40 and the second fitting portion 41
The space between the second pump housing 11 and the second side plate 23 is divided into a first working chamber 42 and a second working chamber 43 by the fitting. A spring 44 for pressing the second side plate 23 toward the second rotor 26 side is inserted in the first working chamber 42, and the first working chamber 42 is provided with a first communication passage 45 formed in the second side plate 21. Connected to the discharge port 23a.
The second working chamber 43 is connected to the discharge port 21a via the second communication passage 47.
It is connected to a pressure chamber 48 which is in communication with. The second communication passage 47 is a communication passage portion formed in the second side plate 23.
46 and a communication hole 34 formed inside the pin 30.

A suction port 21b and a suction port 2 are provided between the inner circumference of the hollow chamber 13 and the outer circumferences of the first rotor 25 and the second rotor 26, respectively.
A first annular groove 50 and a second annular groove 51 communicating with 3b are formed, and the first annular groove 50 communicates with a first flow rate control valve 53 via an intake passage 52 formed in the first pump housing 10. The second annular groove 51 communicates with a second flow rate control valve 55 via an intake passage 54 formed in the second pump housing 11. The discharge port 21a communicates with the first flow rate control valve 53 via the pressure chamber 48 and the discharge passage 56 formed in the first pump housing 10, and the discharge port 23a passes through the first working chamber 42 to the second pump housing 11. It communicates with the second flow control valve 55 via the formed discharge passage 57. First flow control valve 53 and second
The oil whose flow rate is controlled by the flow rate control valve 55 is fed to different fluid devices.

Next, the operation based on the above configuration will be described. When the rotary shaft 24 rotates, the first and second rotors 25 and 26 rotate together, and the vanes 27 move in the radial direction following the inner peripheral cam surfaces 20a and 22a. As a result, the inner peripheral cam surfaces 20a, 22a and the first and second
The volume of the pump chamber formed by partitioning the outer circumferences of the rotors 25, 26 with a plurality of vanes 27 increases and decreases, sucks oil from the suction ports 21b, 23b, and discharges the oil to the discharge ports 21a, 23a. The oil discharged to the discharge port 21a is guided to the first flow rate control valve 53 via the discharge passage 56 and is controlled to a constant flow rate and sent to the fluid device. The oil discharged to the discharge port 23a is guided to the second flow rate control valve 55 through the discharge passage 57, is controlled to have a constant flow rate, and is sent to a fluid device different from the first flow rate control valve 53 side. The oil pressures of the discharge port 21a and the discharge port 23a differ depending on the operating state of the fluid device, and the oil pressure on the discharge port 21a side is the second communication passage 47 including the communication hole 34 and the communication passage portion 46.
Is guided to the second working chamber 43 via the, and the pressure of the oil on the discharge port 23a side is guided to the first working chamber 42 via the first communication passage 45. As a result, on the surface of the second side plate 23 opposite to the second rotor 26, the surface corresponding to the first working chamber 42 and the second working chamber 43 are formed.
Different oil pressures act on the surface corresponding to. In this way, the pressure of the oil acting on the surface of the first side plate 21 on the first rotor 25 side and the second pressure of the second side plate 23
The second side plate 23 can be pressed against the second rotor 26 side from the first and second working chambers 42, 43 side with a pressure corresponding to the pressure of the oil acting on the surface on the rotor 26 side.

According to the above-described embodiment, oil does not leak from the communication hole 34 for guiding the oil pressure of the discharge port 21a to the second working chamber 43, and a large cross-sectional area of the communication hole 34 can be obtained. It is possible to introduce a sufficient amount of oil, and the oil pressure rise failure does not occur.

<Effect of the Invention> As described above, the present invention has a configuration in which the communication hole is formed inside the pin attached to the pump housing, and the communication hole guides the oil on the first rotor side to the second working chamber. Since there is, the first side plate, the second cam ring, the second
No oil leaks between the side plates. Further, since the cross-sectional area of the communication hole can be made large, a sufficient amount of oil can be introduced, and the oil pressure rise failure does not occur.

[Brief description of drawings]

FIG. 1 is a vertical sectional view of a tandem pump of the present invention, and FIG. 2 is a vertical sectional view of a conventional tandem pump. 10 ... First pump housing, 11 ... Second pump housing, 13 ... Hollow chamber, 20 ... First cam ring, 21 ... First side plate, 22 ... Second cam ring, 23 ... Second
Side plate, 30 ... pin, 34 ... communication hole, 42 ... first working chamber, 43 ... second working chamber, 45 ... first communication passage, 47 ...
… The second passage.

Claims (1)

[Scope of utility model registration request] 1. A first cam ring, a first side plate, a second cam ring, and a second side plate are sequentially fitted into a hollow chamber of a pump housing, and a rotary shaft is rotated around a center of the first and second cam rings in the pump housing. A vane that slides in contact with the inner peripheral cam surface of the first cam ring and a vane that slidably contacts the inner peripheral cam surface of the second cam ring can be slid in the radial direction. The second rotor held by the rotary shaft is rotatably connected to the rotary shaft, the first and second cam rings are supported by pins attached to the pump housing, and the first fitting portion is provided on the end surface of the pump housing on the second side plate side. And a second fitting portion slidably fitted to the first fitting portion on the end surface of the second side plate, and the second side plate of the hollow chamber is formed by the first and second fitting portions. Side end face and First the space between the second side plates
In the tandem pump, which is divided into the working chamber and the second working chamber, sucks the fluid from the suction port formed in each side plate and discharges the fluid to the discharge port, the discharge on the second rotor side to the second cam ring A first communication passage that connects the port and the first working chamber is formed, and a second communication passage that connects the discharge port of the first rotor and the second working chamber is formed, and the second communication passage is provided inside the pin. The tandem pump is characterized by using the communication hole.