JP2015129458A - vacuum pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vacuum pump which enables reduction of the number of components and also enables a holder to be thinly formed.SOLUTION: A vane pump 1 includes a housing 2 having a pump chamber therein. A suction passage 6 is formed in a part of the housing 2. Further, a non-return valve 52, which introduces air in a power breaking device into the pump chamber of the housing 2 and blocks airflow in an opposite direction to the air introduced to the pump chamber, is provided at the upstream of the suction passage 6. The non-return valve 52 is provided with: a pipe 61 inserted into the housing 2; a valve body 62 disposed in a space formed by the pipe 61 and the housing 2; and a spring (an elastic member) 63 which elastically supports the valve body 62. A receiving part 2E for engaging with an end part of the spring 63 which is located at the opposite side of the valve body 62 is provided at the housing 2.

Description

  The present invention relates to a vacuum pump attached to an engine body.

Conventionally, a vacuum pump used as a vacuum pump for an automobile is known (for example, see Patent Document 1).
A conventional vacuum pump has a housing having a pump chamber inside, and a suction passage for sucking gas (air) from the brake booster to the pump chamber is provided in a part of the housing. A check valve for maintaining the negative pressure of the brake booster is provided upstream of the suction passage.

JP 2004-300970 A

Here, for example, as shown in FIG. 5, the check valve described in Patent Document 1 includes a holder, a valve body disposed in a space provided inside the holder, a spring, and a spring receiving member. A gasket provided between the holder and the housing. For this reason, the number of parts increased, leading to an increase in cost and manufacturing process.
Further, although the spring receiving member is fixed to the inner peripheral surface of the holder, a narrow groove for fixing the spring receiving member is necessary on the inner peripheral surface of the holder. It was necessary to increase the thickness.

  Then, in view of the subject which concerns, this invention provides the vacuum pump which can reduce a number of parts and can make the thickness of a holder thin.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  That is, according to the first aspect of the present invention, the housing has a housing having a pump chamber therein, a suction passage is formed in a part of the housing, gas is introduced upstream of the suction passage, and air in the opposite direction is introduced. In the vacuum pump provided with a check valve that blocks the flow of the valve, the check valve includes a pipe inserted into the housing, a valve body disposed in a space formed by the pipe and the housing, and the valve An elastic member for elastically supporting the body, and a receiving portion for locking the elastic member is provided on the housing.

  According to a second aspect of the present invention, the pipe is fixed by being press-fitted into the housing.

  According to a third aspect of the present invention, the pipe is fixed by caulking the housing.

  According to a fourth aspect of the present invention, the receiving portion includes a locking portion for locking the end portion of the elastic member and a passage communicating with the suction passage, and the locking portion is pumped more than the passage. It is formed so as to be recessed toward the chamber side.

  As effects of the present invention, the following effects can be obtained.

  That is, in claim 1, since the receiving member can be omitted as compared with the conventional check valve, the number of parts can be reduced, and the work process and cost can be reduced. Further, since it is not necessary to provide a groove for fixing the receiving portion on the inner peripheral surface of the pipe, the thickness of the pipe can be reduced, and the cost can be reduced.

  According to the second aspect, since the gasket can be omitted as compared with the conventional check valve, the work process and cost can be reduced.

  According to the third aspect, since the gasket can be omitted as compared with the conventional check valve, the work process and cost can be reduced.

  The elastic member can be stably supported.

Sectional drawing which shows the vacuum pump which concerns on embodiment of this invention. The AA line sectional view of Drawing 1 concerning the embodiment of the present invention. Sectional drawing which shows the non-return valve which concerns on embodiment of this invention. Sectional drawing which shows the non-return valve which concerns on 2nd embodiment of this invention. Sectional drawing which shows the non-return valve which concerns on a prior art.

Reference numeral 1 denotes a vane pump as a vacuum pump. The vane pump 1 is fixed to a side surface of an engine room (not shown), and functions as a negative pressure source of a brake booster (not shown), for example.
The vane pump 1 includes a stepped cylindrical housing 2 having a substantially circular pump chamber 2A, a rotor 3 that is disposed in the pump chamber 2A, and is disposed with its axis eccentric with respect to the center of the pump chamber 2A. The vane 4 that is disposed in the pump chamber 2A and rotated in the direction of the arrow together with the rotor 3 to always partition the pump chamber 2A into a plurality of working spaces 2a to 2c, and the opening of the large-diameter portion 2B in the housing 2, that is, And a cover 5 that closes one end opening of the pump chamber 2A.

  The housing 2 has a large-diameter portion 2B whose inside is the pump chamber 2A, a medium-diameter portion 2C formed at a position adjacent to the end surface of the large-diameter portion 2B, and a small-diameter portion 2D that is adjacent to the medium-diameter portion 2C. The rotor 3 is rotatably supported by the inner peripheral surfaces of the medium diameter portion 2C and the small diameter portion 2D. The large diameter portion 2B of the housing 2 is provided with a suction passage 6 for sucking gas (air) from the brake booster to the pump chamber 2A, and upstream of the suction passage 6, the brake booster is provided. A check valve 52 is provided to maintain the negative pressure of the device. Further, an axial through hole penetrating from the pump chamber 2A to the end face of the housing 2 is formed in the middle diameter portion 2C adjacent to the lowermost portion of the pump chamber 2A. 2 is a discharge passage 7 for discharging gas to the outside. As will be described in detail later, a reed valve 8 is provided on the end surface of the housing 2 to open and close the discharge passage 7 when necessary.

A guide groove 3A in the diameter direction is formed at one end of the rotor 3 in the pump chamber 2A in the axial direction, and a plate-like vane 4 is slidably attached to the guide groove 3A in the diameter direction. Caps 4 </ b> A that slide on the inner peripheral surface of the pump chamber 2 </ b> A are attached to both ends of the vane 4. As shown in FIG. 1, when the rotor 3 and the vane 4 are rotated in the direction of the arrow, both caps 4A slide while maintaining airtightness with the inner peripheral surface of the pump chamber 2A, and the axial direction of the vane 4 Both end surfaces 4B and 4B slide with the inner wall surface of the cover 5 and the inner wall surface of the pump chamber 2A, and a part of the outer peripheral surface of the rotor 3 is maintained in contact with the inner peripheral surface of the pump chamber 2A. . Thereby, the inside of the pump chamber 2A is partitioned as the operation spaces 2a to 2c that can be expanded and contracted.
An oil supply passage 11 is formed across the shaft portion on the other end side of the rotor 3 and the inner peripheral surface of the housing 2. The oil supply passage 11 is drilled in the shaft portion of the rotor 3 and is connected to the oil supply pipe 12, the diameter direction hole 3 </ b> C continuous from the other end of the axial direction hole 3 </ b> B, and the rotor 3. When rotated in the direction of the arrow, it is composed of an axial groove 2G of the housing 2 that intermittently communicates with the diameter direction hole 3C.

When the engine is driven, the rotor 3 and the vane 4 are rotated in the direction of the arrow in FIG. 1 in conjunction with the driving of the engine, so that the volumes of the three working spaces 2a to 2c are expanded and contracted. Along with this, the gas (air) in the brake booster is sucked into the working spaces 2a to 2c through the suction passage 6, and the gas in the working spaces 2a to 2c is discharged into the discharge passage 7 and open. It is discharged into the engine room, which is the outside of the pump chamber 2A, through the reed valve 8 in the state of being made. Further, when the rotor 3 and the vane 4 are rotated as described above, the lubricating oil is supplied to the sliding portion of the pump chamber 2 </ b> A and the vane 4 through the oil supply passage 11. The lubricating oil flowing into the pump chamber 2A is primarily stored in the lower portion of the pump chamber 2A and then moved by the rotating vane 4 and its cap 4A, and then the discharge passage 7 and the open reed valve 8 are opened. It is discharged into the engine room, which is outside the pump chamber 2A.
The configuration is not different from the configuration of a conventionally known vane pump disclosed in Patent Document 1, for example.

Next, a detailed configuration of the check valve 52 provided in the suction passage 6 of the housing 2 according to the present embodiment will be described.
The check valve 52 includes a pipe 61 inserted into the housing 2, a valve body 62 disposed in a space formed by the pipe 61 and the housing 2, and a spring 63 that is an elastic member that elastically supports the valve body 62. And.
The pipe 61 is provided with a suction passage 61a for sucking air therein. Further, the outer diameter of the end portion 61 b in the insertion direction to the housing 2 is configured to be slightly larger than the inner diameter of the suction port 50. The pipe 61 is a sheet metal pipe formed by processing a material plate into an annular shape.
The valve body 62 is provided so as to be movable in the longitudinal direction of the space formed by the pipe 61 and the housing 2, and a spring 63 is in contact with the surface on the housing 2 side. It is elastically supported while being biased.
The spring 63 is a member that elastically supports the valve body 62, one end is in contact with the valve body 62, and the other end on the housing 2 side is in contact with a receiving portion 2 </ b> E for fixing and supporting the spring 63.
The receiving portion 2E is provided on the bottom surface of the suction port 50, and a projection having a trapezoidal cross-sectional shape is formed at the center. The receiving portion 2 </ b> E includes a locking portion 64 for locking the end portion of the spring 63 and a passage 65 communicating with the suction passage 6. The locking portion 64 is a portion surrounded by a bottom surface of the suction port 50, a projection having a trapezoidal shape in cross section provided in the center, and a side surface of the suction port 50, and the bottom surface of the suction port 50 is on the valve body side of the passage 65. That is, the locking portion 64 is formed so as to be recessed from the passage 65 toward the pump chamber 2A.

  With this configuration, when the pressure in the pump chamber 2A of the housing 2 becomes negative pressure, the check valve 52 opens and sucks gas (air) from the brake booster to the pump chamber 2A through the suction passage 6. It is made to do.

  When fixing the pipe 61 to the housing 2, the pipe 61 is fixed while being pressed into the housing 2. With this configuration, the pipe 61 can be fixed to the suction port 50 without providing a gasket.

  Moreover, the vane pump 1 which concerns on another embodiment is demonstrated using FIG. In addition, about structures other than the structure of a non-return valve, since it is the structure similar to the vane pump 1 which concerns on 1st embodiment, description is abbreviate | omitted.

The check valve 52 includes a pipe 61 inserted into the housing 2, a valve body 62 disposed in a space formed by the pipe 61 and the housing 2, and a spring 63 that is an elastic member that elastically supports the valve body 62. And.
The pipe 61 is provided with a suction passage 61a for sucking air therein. In addition, the end portion 61b in the insertion direction to the housing 2 is formed such that the cross-sectional diameter increases toward the end portion, and the outer diameter of the distal end portion is configured to be slightly larger than the inner diameter of the suction port 50. Yes.
The valve body 62 is provided so as to be movable in the longitudinal direction of the space formed by the pipe 61 and the housing 2, and a spring 63 is in contact with the surface on the housing 2 side. It is elastically supported while being biased.
The spring 63 is a member that elastically supports the valve body 62, one end is in contact with the valve body 62, and the other end on the suction port 50 side is in contact with the receiving portion 2 </ b> E for fixing and supporting the spring 63. .
The receiving portion 2E is provided on the bottom surface of the suction port 50, and a projection having a trapezoidal cross-sectional shape is formed at the center. The receiving portion 2 </ b> E includes a locking portion 64 for locking the end portion of the spring 63 and a passage 65 communicating with the suction passage 6. The locking portion 64 is a portion surrounded by a bottom surface of the suction port 50, a projection having a trapezoidal cross-sectional view provided in the center, and a side surface of the suction port 50, and the bottom surface of the suction port 50 is the valve body side of the passage 65. It is provided on the pump chamber 2A side with respect to the end face. That is, the locking portion 64 is formed so as to be recessed toward the pump chamber 2 </ b> A from the passage 65.

  With this configuration, when the pressure in the pump chamber 2A of the housing 2 becomes negative pressure, the check valve 52 opens and sucks gas (air) from the brake booster to the pump chamber 2A through the suction passage 6. It is made to do.

A caulking portion 2F is formed on the outermost end surface of the housing 2. The caulking portion 2F is formed in a cylindrical shape.
When fixing the pipe 61 to the housing 2, the pipe 61 is inserted in the direction of the housing 2 and is fixed by compressing the caulking portion 2 </ b> F to the inner diameter side. By comprising in this way, the pipe 61 can be fixed to the housing 2 without providing a gasket.

As described above, the suction passage 6 is formed in the housing 2 having the pump chamber 2 </ b> A inside, and a part of the housing 2, and the gas is introduced upstream of the suction passage 6 and air flows in the opposite direction. In the vane pump 1 provided with the check valve 52 that blocks the check valve 52, the check valve 52 includes a pipe 61 inserted into the housing 2, a valve body 62 disposed in a space formed by the pipe 61 and the housing 2, and A spring 63 that elastically supports the valve body 62 is provided, and a receiving portion 2E for locking the spring 63 is provided on the housing 2.
By comprising in this way, since a receiving member can be omitted compared with the conventional check valve, a number of parts can be reduced and a work process and cost can be reduced. Further, since it is not necessary to provide a groove for fixing the receiving portion on the inner peripheral surface of the pipe 61, the thickness of the pipe 61 can be reduced, and the cost can be reduced.

The pipe 61 is fixed by being press-fitted into the housing 2.
By comprising in this way, since a gasket can be omitted compared with the conventional check valve, a work process and cost can be reduced.

The pipe 61 is obtained by caulking and fixing the housing 2.
By comprising in this way, since a gasket can be omitted compared with the conventional check valve, a work process and cost can be reduced.

1 Vane pump (vacuum pump)
2 housing 2A pump chamber 2B large diameter portion 2C medium diameter portion 2D small diameter portion 2E receiving portion 2F caulking portion 3 rotor 3A guide groove 3B axial hole 3C diameter direction hole 4 vane 4A cap 4B both end surfaces 5 cover 6 suction passage 7 discharge passage 8 Reed Valve 52 Check Valve 61 Pipe 61a Discharge Passage 61b Insertion Direction End 62 Valve Element 63 Spring (Elastic Member)

Claims (4)

Having a housing with a pump chamber inside,
Forming a suction passage in a part of the housing;
In the vacuum pump provided with a check valve for blocking the flow of air in the reverse direction while introducing gas into the pump chamber of the housing upstream of the suction passage,
The check valve includes a pipe inserted into the housing, a valve body disposed in a space formed by the pipe and the housing, and an elastic member that elastically supports the valve body,
A vacuum pump, wherein the housing is provided with a receiving portion for locking the elastic member. The vacuum pump according to claim 1, wherein the pipe is press-fitted into the housing and fixed. The vacuum pump according to claim 1, wherein the pipe is fixed by caulking the housing. The receiving portion has a locking portion for locking an end portion of the elastic member and a passage communicating with the suction passage, and the locking portion is recessed toward the pump chamber side than the passage. The vacuum pump according to any one of claims 1 to 3, wherein the vacuum pump is formed.

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