WO2016035553A1

WO2016035553A1 - Electric vane pump

Info

Publication number: WO2016035553A1
Application number: PCT/JP2015/073265
Authority: WO
Inventors: 浩一朗赤塚; 藤田　朋之; 智行中川; 史恭加藤; 裕希五味
Original assignee: Ｋｙｂ株式会社
Priority date: 2014-09-02
Filing date: 2015-08-19
Publication date: 2016-03-10
Also published as: JP2016050574A

Abstract

An electric vane pump 100 comprises: a motor shaft 4 rotatably supported by a motor housing 3 through bearings 2a, 2b; a pump housing 40 connected to the motor housing 3 and having a pump accommodation part 40a; a pump rotor 31 connected to the motor shaft 4 and accommodated in the pump accommodation part 40a; a plurality of vanes 32 enabled to reciprocate in the radial direction with respect to the pump rotor 31; a cam ring 33 accommodating the pump rotor 31 and having an inner circumferential surface which is in sliding contact with the end portions of the vanes 32 according to the rotation of the pump rotor 31; and a positioning pin 50 for determining the position of the cam ring 33 with respect to the motor housing 3.

Description

Electric vane pump

The present invention relates to an electric vane pump.

JP2011-117391A discloses an electric vane pump driven by the power of an electric motor.

In the electric vane pump disclosed in JP2011-117391A, the cam ring is positioned with respect to the pump cover via a pin, while the motor rotating shaft is positioned with respect to the pump housing and the motor housing via a bearing.

For this reason, when the positioning accuracy of the pump cover and the pump housing is poor, the coaxiality between the cam ring and the motor rotation shaft is deteriorated, so that the vibration of the pump rotor with respect to the cam ring is increased. When the vibration of the pump rotor with respect to the cam ring is large, noise is likely to occur.

An object of the present invention is to provide an electric vane pump capable of suppressing the generation of noise.

According to an aspect of the present invention, an electric vane pump, a motor shaft rotatably supported by a motor housing via a bearing, a pump housing connected to the motor housing and having a pump housing portion formed therein, A pump rotor coupled to the motor shaft and accommodated in the pump accommodating portion, a plurality of vanes provided so as to be capable of reciprocating in the radial direction with respect to the pump rotor, and accommodating the pump rotor and the pump rotor And a cam ring in which the tip of the vane is slidably contacted with an inner peripheral surface as the motor rotates, and a positioning pin for positioning the cam ring with respect to the motor housing.

FIG. 1 is a cross-sectional view of the electric vane pump according to the first embodiment of the present invention. FIG. 2 is a sectional view of an electric vane pump according to the second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<First Embodiment>
With reference to FIG. 1, the electric vane pump 100 which concerns on 1st Embodiment of this invention is demonstrated.

The electric vane pump 100 is used, for example, as a hydraulic supply source that supplies hydraulic oil (working fluid) to hydraulic equipment such as a continuously variable transmission mounted on a vehicle.

The electric vane pump 100 includes an electric motor 1 and a vane pump 30 that is driven by the power of the electric motor 1 and supplies hydraulic oil to hydraulic equipment.

The electric motor 1 includes a motor shaft 4 rotatably supported by a motor housing 3 via

bearings

2a and 2b, a motor rotor 5 having a plurality of permanent magnets arranged in the circumferential direction and fixed to the motor shaft 4, a motor A stator 6 fixed to the inner periphery of the housing 3 and wound with a coil. The motor rotor 5 and the stator 6 are arranged concentrically, and a slight gap exists between them.

The motor housing 3 includes a substantially bottomed cylindrical main body 3a and a motor cover 3b that closes the opening of the main body 3a and is connected to the vane pump 30. The main body 3a and the motor cover 3b are assembled together by fitting an annular spigot 3c formed on the motor cover 3b to the inner peripheral surface of the main body 3a.

The bearing 2a is fixed to the bottom of the main body 3a, and the bearing 2b is fixed to the inner peripheral surface of the hollow 3d of the motor cover 3b. The motor shaft 4 is rotatably supported by two

bearings

2a and 2b, and one end side of the motor shaft 4 is inserted into the interior of the pump housing 40 of the vane pump 30 through the hollow portion 3d of the motor cover 3b. The

The vane pump 30 houses a pump rotor 31 connected to the motor shaft 4, a plurality of vanes 32 provided so as to be capable of reciprocating in the radial direction with respect to the pump rotor 31, and the rotation of the pump rotor 31. Accordingly, a cam ring 33 in which the tip of the vane 32 is in sliding contact with the inner cam surface is provided.

In the cam ring 33, a plurality of pump chambers 34 are defined by the outer peripheral surface of the pump rotor 31, the cam surface of the cam ring 33, and the adjacent vanes 32.

The cam ring 33 is an annular member having a substantially elliptical cam surface. The cam surface of the cam ring 33 includes two suction regions that expand the volume of the pump chamber 34 as the pump rotor 31 rotates, and two discharge regions that contract the volume of the pump chamber 34 as the pump rotor 31 rotates. Have.

A first side plate 36 as a plate member is disposed in contact with one side of the pump rotor 31 and the cam ring 33, and a second side plate 37 is disposed in contact with the other side. As described above, the first side plate 36 and the second side plate 37 are arranged with both side surfaces of the pump rotor 31 and the cam ring 33 sandwiched therebetween, and define the pump chamber 34.

The pump rotor 31, the cam ring 33, the first side plate 36, and the second side plate 37 are accommodated in a pump accommodating portion 40a formed in the pump housing 40 in a concave shape. The opening of the pump housing part 40 a is closed by the motor cover 3 b of the motor housing 3.

Two suction ports (not shown) are formed on the outer periphery of the first side plate 36 by cutting them into an arc shape. The two suction ports open corresponding to the two suction areas of the cam ring 33 and guide the hydraulic oil to the pump chamber 34.

In the second side plate 37, two discharge ports (not shown) are formed penetrating in an arc shape. The two discharge ports open corresponding to the discharge region of the cam ring 33 and discharge the hydraulic oil in the pump chamber 34.

In the pump housing 40, a suction passage 41 communicating with the two suction ports of the first side plate 36 is formed along the inner peripheral surface of the pump housing portion 40a. A high pressure chamber 42 communicating with the two discharge ports of the second side plate 37 is formed in an annular shape on the bottom surface of the pump housing portion 40 a of the pump housing 40. The high pressure chamber 42 is partitioned by the second side plate 37 disposed on the bottom surface of the pump housing portion 40a.

When the motor shaft 4 is rotated by driving the electric motor 1, the pump rotor 31 connected to the motor shaft 4 is rotated, and accordingly, each pump chamber 34 in the cam ring 33 is sucked through the suction port of the first side plate 36. The hydraulic oil is sucked from the passage 41 and is discharged to the high pressure chamber 42 through the discharge port of the second side plate 37. Thus, each pump chamber 34 in the cam ring 33 supplies and discharges hydraulic oil by expansion and contraction accompanying the rotation of the pump rotor 31. The hydraulic oil discharged to the high pressure chamber 42 is supplied to the hydraulic equipment.

The relative rotation of the cam ring 33, the first side plate 36 and the second side plate 37 is restricted by the two positioning pins 50. Thereby, the positioning of the suction region of the cam ring 33 and the suction port of the first side plate 36 and the positioning of the discharge region of the cam ring 33 and the discharge port of the second side plate 37 are performed.

The positioning pin 50 is inserted through the cam ring 33 and the first side plate 36, one end side is inserted into the second side plate 37, and the other end side is inserted into the motor cover 3b. Thus, the cam ring 33, the first side plate 36, and the second side plate 37 are positioned with respect to the motor cover 3b by the positioning pins 50.

The motor cover 3b and the pump housing 40 are positioned by the inlay portion 55 and fastened by the bolt 56. The inlay portion 55 includes a cylindrical portion 55a formed on the end surface of the motor cover 3b, and an annular recess 55b formed on the end surface of the pump housing 40 and into which the cylindrical portion 55a is fitted.

A seal member 57 with which the motor shaft 4 is slidably contacted is provided on the inner peripheral surface of the hollow portion 3d of the motor cover 3b. The sealing member 57 prevents hydraulic fluid from leaking from the vane pump 30 to the electric motor 1.

Next, functions and effects of the electric vane pump 100 according to the first embodiment will be described.

The cam ring 33 is positioned with respect to the motor cover 3b of the motor housing 3 via the positioning pins 50. The motor shaft 4 is rotatably supported by the motor housing 3 via the

bearings

2a and 2b and positioned. Thus, both the cam ring 33 and the motor shaft 4 are positioned with respect to the motor housing 3. That is, the cam ring 33 and the motor shaft 4 are positioned with respect to the same member. Therefore, even if the dimensional accuracy of the spigot portion 55 is poor and the positioning accuracy of the motor cover 3b and the pump housing 40 is poor, the coaxiality between the cam ring 33 and the motor shaft 4 does not deteriorate. Therefore, vibration of the pump rotor 31 with respect to the cam ring 33 can be suppressed, and generation of noise can be suppressed.

Further, the motor shaft 4 is supported only by the motor housing 3 through the

bearings

2a and 2b. That is, one end side of the motor shaft 4 is formed by extending through the hollow portion 3d of the motor cover 3b and extending into the pump housing portion 40a of the pump housing 40, but the one end side is not supported by the bearing. It is a free end. Thus, since the motor shaft 4 is supported only by the motor housing 3 and is not supported by the pump housing 40, the motor shaft 4 is accurately positioned with respect to the motor housing 3. Therefore, both the cam ring 33 and the motor shaft 4 can be reliably positioned with respect to the motor housing 3, so that the swing of the pump rotor 31 with respect to the cam ring 33 can be suppressed.

Further, the pump housing 40 is not provided with a pump cover for closing the pump housing portion 40a, and the pump housing portion 40a is closed by the motor cover 3b. Therefore, the number of parts can be reduced by the amount that the pump cover is not provided.

Further, since the first side plate 36 is provided between the motor cover 3 b and the cam ring 33, the pump chamber 34 can be partitioned inside the cam ring 33 and the hydraulic oil is guided from the suction passage to the pump chamber 34. be able to.

Second Embodiment
With reference to FIG. 2, the electric vane pump 200 which concerns on 2nd Embodiment of this invention is demonstrated. Below, it demonstrates centering on a different point from the said 1st Embodiment, and attaches | subjects the same code | symbol to the structure which has the same function as the electric vane pump 100 which concerns on the said 1st Embodiment, and abbreviate | omits description. .

The electric vane pump 200 is different from the first embodiment in that a pump cover 43 as a plate member is provided in the pump housing 40 instead of the first side plate 36 provided in the electric vane pump 100.

The pump cover 43 is fastened to the pump housing 40 by bolts 61 so as to close the pump housing portion 40a, and is provided between the motor cover 3b and the cam ring 33.

In the electric vane pump 200, a suction port that guides hydraulic oil to the pump chamber 34 is formed in the pump cover 43.

The motor cover 3b and the pump cover 43 are positioned by the spigot part 60. The inlay portion 60 includes a cylindrical portion 60a formed on the end surface of the pump cover 43 and an annular recess 60b formed on the end surface of the motor cover 3b and into which the cylindrical portion 60a is fitted.

In the electric vane pump 200, the positioning pin 50 is inserted through the cam ring 33 and the pump cover 43, one end side is inserted into the second side plate 37, and the other end side is inserted into the motor cover 3b. Thus, also in the electric vane pump 200, the cam ring 33 is positioned with respect to the motor cover 3b by the positioning pins 50.

Also in the electric vane pump 200 according to the second embodiment, the cam ring 33 is positioned with respect to the motor cover 3b of the motor housing 3 via the positioning pins 50, and the motor shaft 4 is positioned via the

bearings

2a and 2b. And is rotatably supported and positioned. Thus, both the cam ring 33 and the motor shaft 4 are positioned with respect to the motor housing 3. Therefore, even if the dimensional accuracy of the spigot part 60 is poor and the positioning accuracy of the motor cover 3b and the pump cover 43 is poor, the coaxiality between the cam ring 33 and the motor shaft 4 does not deteriorate. Therefore, vibration of the pump rotor 31 with respect to the cam ring 33 can be suppressed, and generation of noise can be suppressed.

The electric vane pump 200 is provided with a pump cover 43, but the pump cover 43 is provided in place of the first side plate 36 of the electric vane pump 100, so that the number of parts is increased as compared with the electric vane pump 100. There is nothing.

Further, since the pump cover 43 is provided between the motor cover 3b and the cam ring 33, the pump chamber 34 can be partitioned inside the cam ring 33, and the hydraulic oil can be guided from the suction passage to the pump chamber 34. it can.

Hereinafter, the configuration, operation, and effect of the embodiment of the present invention will be described together.

In the present embodiment, the electric vane pumps 100 and 200 are connected to the motor shaft 4 rotatably supported by the motor housing 3 via

bearings

2a and 2b, and the pump housing portion 40a is connected to the motor housing 3. A housing 40, a pump rotor 31 connected to the motor shaft 4 and housed in a pump housing portion 40a, a plurality of vanes 32 provided so as to be capable of reciprocating in the radial direction with respect to the pump rotor 31, and a pump rotor 31 A cam ring 33 that accommodates the tip of the vane 32 in sliding contact with the inner peripheral surface as the pump rotor 31 rotates and a positioning pin 50 that positions the cam ring 33 with respect to the motor housing 3 are provided.

In this configuration, since the cam ring 33 is positioned with respect to the motor housing 3 that rotatably supports the motor shaft 4, it is possible to suppress the vibration of the pump rotor 31 with respect to the cam ring 33. Therefore, generation of noise can be suppressed.

In this embodiment, the motor shaft 4 is supported only by the motor housing 3 via the

bearings

2a and 2b.

In this configuration, since the motor shaft 4 is supported only by the motor housing 3 and not by the pump housing 40, the motor shaft 4 is accurately positioned with respect to the motor housing 3. Therefore, both the cam ring 33 and the motor shaft 4 can be reliably positioned with respect to the motor housing 3, so that the swing of the pump rotor 31 with respect to the cam ring 33 can be suppressed.

Further, in the present embodiment, a plate member (first side plate 36, pump cover 43) provided between the motor housing 3 and the cam ring 33 is provided, and the positioning pin 50 is provided through the plate member.

In this configuration, since the plate member is provided between the motor housing 3 and the cam ring 33, the pump chamber 34 can be partitioned inside the cam ring 33, and the hydraulic oil is guided from the suction passage 41 to the pump chamber 34. be able to.

The embodiment of the present invention has been described above. However, the above embodiment only shows a part of application examples of the present invention, and the technical scope of the present invention is limited to the specific configuration of the above embodiment. Absent.

This application claims priority based on Japanese Patent Application No. 2014-178300 filed with the Japan Patent Office on September 2, 2014, the entire contents of which are incorporated herein by reference.

Claims

A motor shaft rotatably supported by a motor housing via a bearing;
A pump housing connected to the motor housing and formed with a pump housing portion;
A pump rotor coupled to the motor shaft and housed in the pump housing portion;
A plurality of vanes provided so as to freely reciprocate in the radial direction with respect to the pump rotor;
A cam ring that houses the pump rotor and the tip of the vane is in sliding contact with the inner peripheral surface as the pump rotor rotates;
A positioning pin for positioning the cam ring with respect to the motor housing;
Electric vane pump with
The electric vane pump according to claim 1,
The motor shaft is an electric vane pump that is supported only by the motor housing via the bearing.
The electric vane pump according to claim 1,
A plate member provided between the motor housing and the cam ring;
The positioning pin is an electric vane pump provided through the plate member.