KR101279816B1 - Vacuum pump bracket and vacuum pump for automobile brake system - Google Patents

Abstract

The present invention relates to a vacuum pump bracket for an automobile brake system that can easily and stably fix a vacuum pump applied to a brake system of an electric vehicle.
The vacuum pump bracket includes a mounting frame to which the body of the vacuum pump is mounted; and a fixed frame extending perpendicular to a plane formed by the mounting frame at one side of the mounting frame; and fixed on the same plane as the fixed frame. One or more fixed legs protruding from the frame; configured to fix the vacuum pump to a lateral surface disposed in parallel with the vacuum pump,
The brake system can easily fix the vacuum pump to any side of the vehicle body to facilitate the fixing of the vacuum pump and to prevent the vibration of the vacuum pump during frequent brake operation, thereby improving the operation reliability of the brake system. Provide the effect of improving.

Description

Vacuum pump bracket and vacuum pump for vehicle brake system {VACUUM PUMP BRACKET AND VACUUM PUMP FOR AUTOMOBILE BRAKE SYSTEM}

The present invention relates to a vehicle brake system, and more particularly, a vacuum pump bracket for an automobile brake system and a bracket for integrally providing a vacuum pump applied to a brake system of an electric vehicle. It relates to a vacuum pump.

In general, a braking system of a motor vehicle using engine power stores a part of the flow rate discharged from a hydraulic pump for a power steering device driven by the engine at a high pressure in the accumulator and performs a boosting operation when braking the vehicle.

On the other hand, instead of the engine, the power source of the battery is used as the power source, and the braking system of the electric vehicle allows the vehicle to be braked by the backing force using the vacuum.

FIG. 1 is a view illustrating a braking apparatus for a conventional electric vehicle, which will be described below with reference to FIG. 1.

In the conventional brake system of the automobile, the brake pedal is powered by a vacuum booster 400 which is powered by the difference between the vacuum pressure and the atmospheric pressure, and is applied to the hydraulic discharge action of the master cylinder installed to cooperate with the vacuum booster 400. As a result, disc brakes or drum brakes provided on the front and rear wheels of the vehicle are configured to brake.

The vacuum booster 400 includes a diaphragm installed in a predetermined housing to separate the vacuum chamber and the atmospheric pressure chamber, and a piston interlocked with the brake pedal at the center of the diaphragm. The vacuum inside the vacuum chamber may be formed by a separate vacuum generator, and the vacuum generator may be connected to the vacuum switch 60 and the vacuum tank 300 by the vacuum switch 2 and the check valve 50. It is configured to include).

The vacuum generator 50 has a structure in which the vacuum pump 200 is operated by the driving of the electric motor to maintain the vacuum state of a constant pressure inside the vacuum tank 300.

When the vacuum switch 2 in the vacuum tank 300 becomes the preset pressure of the vacuum switch 2 and the vacuum switch 2 is turned off, the operation of the electric pump 60 is stopped. On the contrary, when the pressure in the vacuum tank 300 is lowered and the vacuum switch 2 is turned on, the driving of the vacuum switch 2 is started. In this motor, the pressure in the vacuum tank 54 is set to the pressure of the vacuum switch 2. It will only be done until it returns to pressure. Therefore, the operation and stop of the vacuum pump 60 is automatically performed according to the pressure in the vacuum tank 300.

As described above, in the case of the electric vehicle of the prior art, the vacuum pump 60 is also frequently operated by the frequent brake operation while driving to maintain the vacuum tank 300 inside the vacuum state. Accordingly, the vacuum pump 60 is frequently vibrated by the frequent operation during driving.

When the vacuum pump 60 is continuously exposed to such vibrations, the coupling part may loosen, which may cause a problem that the brake system may not operate normally due to the inflow of air.

Accordingly, in the prior art, when the vacuum pump 60 is fixed, the wire is fixed by using wires, or the vacuum pump body is fixed by a method of mounting the shape thereof. However, the fixing method using wires is a method of vacuum pump 60. It is not possible to guarantee a stable fixation, the fixing operation is difficult, and the shape processing has a problem that makes the fixing operation of the vacuum pump 60 more difficult.

Accordingly, an object of the present invention is to provide a vacuum pump bracket for an automobile brake system that enables the vacuum pump to be easily and firmly fixed to a vehicle body in order to solve the problems caused by the vibrations applied to the vacuum pump of the prior art. .

Another object of the present invention is to provide a vacuum pump for an automobile brake system, in which a vacuum pump bracket is integrally formed to easily and firmly fix the vacuum pump to a vehicle body in order to solve the problems caused by the vibration applied to the vacuum pump. It is done.

Vacuum pump bracket of the present invention for achieving the above object, a mounting frame to which the body of the vacuum pump is mounted; and a fixed frame extending perpendicular to the plane formed by the mounting frame on one side of the mounting frame; And at least one fixing leg protruding from the fixing frame on the same plane as the fixing frame, wherein the vacuum pump is fixed to a lateral surface disposed in parallel with the vacuum pump. .

Vacuum pump bracket having another configuration of the present invention for achieving the above object, the mounting frame is mounted to the body of the vacuum pump; and the mounting plane on each of the same plane formed by the mounting frame on both sides of the mounting frame One or more fixed legs extending in the lateral direction of the frame; comprising a, the vacuum pump in a fixed surface disposed to cross the longitudinal direction of the vacuum pump on both sides of the vacuum pump, the longitudinal direction of the vacuum pump intersects the fixed surface It is characterized in that it is configured to fix the vacuum pump to face the direction.

Vacuum pump bracket having another configuration of the present invention for achieving the above object, the mounting frame to which the body of the vacuum pump is mounted; and in one direction of the mounting frame in a direction perpendicular to the plane formed by the mounting frame One or more fixed legs extending; is formed, characterized in that configured to fix the vacuum pump to a fixed surface disposed in parallel with the longitudinal direction of the vacuum pump on one side of the vacuum pump.

Vacuum pump of the present invention for achieving the above object, the mounting frame is mounted to the body of the vacuum pump; and a fixed frame extending perpendicular to the plane formed by the mounting frame on one side of the mounting frame; One or more fixed legs protruding from the fixed frame on the same plane as the fixed frame; including a vacuum pump bracket configured to fix the vacuum pump to a side surface disposed in parallel with the vacuum pump to the vacuum pump body Characterized in that formed integrally.

Vacuum pump having another configuration of the present invention for achieving the above object, the mounting frame is mounted on the body of the vacuum pump; and the mounting frame on the same plane as the plane formed by the mounting frame on both sides of the mounting frame, respectively At least one fixed leg extending in a lateral direction of the vacuum pump including a vacuum pump including a direction in which the longitudinal direction of the vacuum pump intersects the fixed surface and is disposed on both sides of the vacuum pump, The vacuum pump bracket is configured to be fixed to the vacuum pump so as to be integrally formed on the vacuum pump body.

Vacuum pump having another configuration of the present invention for achieving the above object, the mounting frame to which the body of the vacuum pump is mounted; and extending in a direction perpendicular to the plane formed by the mounting frame on one side of the mounting frame A vacuum pump bracket for fixing the vacuum pump to a fixed surface disposed in parallel with the longitudinal direction of the vacuum pump at one side of the vacuum pump, including one or more fixed legs formed integrally with the vacuum pump body It is characterized by.

The mounting frames formed on the vacuum pump brackets of the present invention are characterized in that they are formed in an annular shape in which a mounting hole into which the vacuum pump body is inserted is formed in the center thereof.

The fixing legs formed on the vacuum pump brackets of the present invention are characterized in that it further comprises a fixing hole is inserted into the fixture is formed through the central portion.

The fixing hole may be configured to include an insertion groove open at one side.

The vacuum pumps also include a nozzle unit for applying a negative pressure in the vacuum tank; and an elastic resistance unit for applying a force convexly deformed in the direction of the nozzle unit; A diaphragm portion for performing a mechanical switching action on the microswitch portion according to the height of the micro switch portion; It may further comprise a; vacuum switch is coupled to the vacuum pump body is configured so that the deformation for the on and off of the switch unit is performed at different vacuum pressures.

The vacuum pump bracket and the vacuum pump of the present invention having the above-described configuration provide an effect that the brake system can easily fix the vacuum pump to any side of the vehicle body, thereby facilitating the fixing of the vacuum pump.

In addition, the vacuum pump bracket and the vacuum pump of the present invention is firmly supported by the vacuum pump bracket to provide an effect of improving the operating reliability of the brake system by preventing the vibration generated in the vacuum pump during frequent brake operation.

1 is a block diagram of a conventional vehicle braking device,
2 is a perspective view of a vacuum pump bracket 500 of the first embodiment of the present invention,
3 is a perspective view of a vacuum pump 200 of the first embodiment in which the vacuum pump bracket 500a of the first embodiment of the present invention is mounted;
4 is a plan view of a vacuum pump bracket 500a of a second embodiment of the present invention;
5 is a side view of the vacuum pump 200a of the second embodiment in which the vacuum pump bracket 500a of the second embodiment of the present invention is integrally formed;
6 is a perspective view of a vacuum pump bracket 500b of the third embodiment of the present invention;
7 is a side view of the vacuum pump 200b of the third embodiment in which the vacuum pump bracket 500b of the third embodiment of the present invention is integrally formed;
8 is a cross-sectional view of the vacuum switch 100 mounted on the vacuum pumps 200, 200a and 200b of the present invention.

Hereinafter, with reference to the accompanying drawings showing an embodiment of the present invention will be described in more detail the present invention.

In the present invention, the 'fixed surface' refers to a wall surface of the outside of the vacuum pump to which the fixed frame or the fixed leg of the vacuum pump bracket is attached in close contact, that is, the vacuum pump is omitted.

2 is a perspective view of a vacuum pump bracket 500 of the first embodiment of the present invention, and FIG. 3 is a perspective view of the vacuum pump 200 of the first embodiment to which the vacuum pump bracket 500a of the first embodiment of the present invention is mounted. to be.

As shown in FIG. 2, the vacuum pump bracket 500 of the first embodiment includes a mounting frame 510, a fixed frame 520, and a pair of fixed legs 521. The fixed leg may be formed in one or more as necessary.

The mounting frame 510 is formed of an annular ring formed with a mounting hole 511 having an inner diameter shape corresponding to the outer circumference of the vacuum pump body 210 so that the vacuum pump body 210 can be inserted.

The fixed frame 520 extends from one side of the mounting frame 510 in a direction crossing the plane in which the mounting frame 510 is included.

The pair of fixing legs 521 is formed to protrude in a direction crossing the direction in which the fixing frame 520 extends, and a fixing hole 522 is formed at a central portion thereof so that the fixing tool 530 can be inserted therein. The one side of the fixing hole 522 is formed of an insertion groove 523 opened so that the fixing tool 530 can be inserted in the lateral direction.

The vacuum pump bracket 500 of the first embodiment of the above structure is the vacuum pump bracket 210 of the first embodiment of the present invention by the vacuum pump body 210 is inserted into the mounting frame 510 as shown in FIG. It is formed of the vacuum pump 200 of the first embodiment.

In the vacuum pump bracket 500 of the first embodiment and the vacuum pump 200 of the first embodiment of the above configuration, the fixed frame 520 is disposed to extend in the lateral direction along the longitudinal direction of the vacuum pump body 210, The vacuum pump 200 can be easily mounted on a fixed surface formed in parallel with the longitudinal direction of the vacuum pump 200.

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4 is a plan view of a vacuum pump bracket 500a of the second embodiment of the present invention, and FIG. 5 is a vacuum pump 200a of the second embodiment in which the vacuum pump bracket 500a of the second embodiment of the present invention is integrally formed. Side view.

As shown in FIG. 4, the vacuum pump bracket 500a of the second exemplary embodiment of the present invention includes two fixed legs protruding from the mounting frame 510a on the same plane including the mounting frame 510a and the mounting frame 510a. 521a). One or more fixed legs 521a may be formed as necessary.

The mounting frame 510a is formed as an annular frame having a mounting hole 511a penetrated to have an inner diameter corresponding to the outer diameter of the vacuum pump body 210. Vacuum pump fastening holes 512a and 513a having different shapes are formed around the inner diameter of the mounting hole 511a of the mounting frame 510a. The vacuum pump fastening holes 512a and 513a are formed to communicate with fastening holes formed in the vacuum pump body 210. When the vacuum pump body 210 is inserted into the mounting hole 511a of the mounting frame 510a by using a fastener such as a screw, the vacuum pump fastening holes 512a and 513a are connected to the vacuum pump body from the mounting frame 510a. 210 may be fixed to prevent the separation.

The fixing legs 521a are formed to protrude from both sides of the mounting frame 510a to be positioned on a plane including the mounting frame 510a. A fixing hole 522 is formed at the center of the fixing leg 521a to insert the fixing tool 530. An open insertion groove 523 is formed at the side of the fixing hole 522 to allow the fastener 530 to be inserted through the insertion groove 523. Insertion groove 523 also serves to provide a constant buffer play in the case of severe vibration.

The vacuum pump bracket 500a of the second embodiment of the above configuration is fixed to the mounting frame 510a by inserting the vacuum pump body 210 to form the vacuum pump 200a of the second embodiment of the present invention as shown in FIG. 5.

The vacuum pump bracket 500a and the vacuum pump 200a of the second embodiment of the present invention configured as described above may easily fix the vacuum pump 500a between the wall surfaces positioned at both sides of the vacuum pump body 210. do. That is, the fixing legs 521a are tightly fixed by the fixing tool 530 on the fixing surface parallel to the plane formed by the vacuum pump 200a interposed therebetween and the one end protrudes in a state where one end protrudes between the wall surfaces. It is possible to fix the vacuum pump 200a between the walls.

That is, the vacuum pump bracket 500a and the vacuum pump 200a of the second embodiment of the present invention have a fixed surface in which the longitudinal direction of the vacuum pump is fixed to the fixed surface which is disposed to cross the longitudinal direction of the vacuum pump on both sides of the vacuum pump 200a. The vacuum pump can be fixed so that it faces in the direction of intersection.

6 is a perspective view of a vacuum pump bracket 500b of the third embodiment of the present invention, and FIG. 7 is a perspective view of the vacuum pump 200b of the third embodiment in which the vacuum pump bracket 500b of the third embodiment of the present invention is integrally formed. Side view.

6, the vacuum pump bracket 500b according to the third embodiment includes a mounting frame 510b on which the body of the vacuum pump is mounted, and two fixed legs 521b extending from one side of the mounting frame 510b. It is configured to include. The fixed leg 521b may be formed in one or more as necessary.

The mounting frame 510b has a through hole 511b formed therein so as to have an inner diameter shape corresponding to the outer diameter of the vacuum pump body 210. Vacuum pump body fastening holes 512b and 513b are formed on the inner circumferential surface of the mounting hole 511b so that the vacuum pump bracket 500b can be firmly fixed to the vacuum pump body 210 by using a fastener such as a screw.

The fixed legs 521b extend in parallel to the plane including the mounting frame 510b at one side of the mounting frame 510b. A fixing hole 522 through which the fixing tool 530 is coupled is formed in the center of the fixing legs 521b. One side of the fixing hole 522 is opened to form the insertion groove 523 to insert the fixture 530 from the side.

After the vacuum pump body 210 is inserted into the mounting hole 511b of the vacuum pump bracket 500b of the third embodiment, the vacuum pump body fastening holes 512b and 513b are vacuumed using fasteners such as screws. When the pump bracket 500b and the vacuum pump body 210 are firmly fixed, the vacuum pump 200b of the third embodiment in which the vacuum pump bracket 500b having the structure as shown in FIG. 7 is integrally formed is provided.

The vacuum pump 200b of the third embodiment allows the vacuum pump to be easily fixed to a fixed surface disposed in parallel with the longitudinal direction of the vacuum pump at one side of the vacuum pump. That is, it is useful for fixing the vacuum pump in parallel with the ceiling surface, the bottom surface or the side wall surface.

In the above-described embodiment of the present invention, the vacuum pump brackets cannot be selectively used for each installation position of the vacuum pump to facilitate the fixing of the vacuum pump, and improve the fixing reliability of the vacuum pump.

In the above-described embodiment of the present invention, the vacuum pump brackets may be manufactured integrally with the vacuum pump body in the manufacture of the vacuum pump.

The vacuum switch 100 provided in the vacuum pumps 200, 200a, and 200b of the first to third embodiments of the present invention having the above-described configuration is configured to minimize or prevent chattering. 8 is a cross-sectional view of the vacuum switch 100 of the present invention.

As shown in FIG. 8, the vacuum switch 100 includes a nozzle unit 110, a diaphragm unit 130, and a microswitch unit 150. The vacuum switch 100 includes insulation for inflow and insulation of moisture and foreign substances. While the cap 160 seals the area exposed to the outside of the micro switch unit 150, the power line 170 is exposed to the outside so as to be connected to a control unit (not shown) for driving the vacuum pumps 200, 200a and 200b. It is composed.

The vacuum switch 100 of the above configuration is mounted so that the diaphragm portion 130 can change the shape for switching the micro switch portion 150 through the spring member 113 in the nozzle unit 110, and the diaphragm An end portion of the micro switch unit 150 in which the fixed electrode 152 is formed is inserted into the nozzle unit 110 and coupled to the diaphragm unit 130 at an upper portion of the unit 130.

A detailed configuration for switching on / off the vacuum pumps 200, 200a and 200b of the vacuum switch 100 having the above-described overall coupling structure will be described below.

The nozzle unit 110 has a tubular nozzle 111 through which a center thereof is formed to introduce external air to the bottom surface, and communicates the inside of the nozzle unit 110 with the vacuum brake system, and the nozzle 111 protrudes. The driver groove screwed into the nozzle 111 so as to move up and down inside the nozzle 111 by the rotation of the nozzle 111 and the tubular nozzle body 101 whose diameter is expanded in the portion and is opened. The formed screw 112 and one end is supported by the screw 112 and the other end is configured to include a spring member 113 in close contact with the bottom surface of the diaphragm portion (130). The nozzle body 101 is the position where the horizontal outer periphery 131b of the diaphragm 131 is seated after the inner diameter increases at the position where the through hole formed in the nozzle 111 ends, the horizontal outer periphery 131b of the diaphragm 131. ) Has an internal structure in which the inner diameter is further enlarged so that the stepped portion is formed to be seated and supported. The screw 112 is an example of the elastic control of the present invention.

In the nozzle unit 110 having the above-described configuration, the spring member 113 diaphragms by adjusting the position of the screw 112 and the gap between the moving electrode 136 and the fixed electrode 152 in the nozzle 111. The size of the elastic force supporting the portion 130 is adjusted.

The diaphragm 130 includes a diaphragm 131 on which a bottom surface is supported at an upper portion of the spring member 113, and a horizontal outer periphery 131 b of the diaphragm 131. And an upper end of the annular diaphragm guide 133 seated on the upper portion of the horizontal outer periphery 131b of the diaphragm 131 seated on the upper end of the inner step of the nozzle body 101 so as to be in close contact with the stepped portion formed in the inner side of the nozzle unit body 101. A moving electrode 136 is formed at the center and inserted into a through hole formed at the center of the annular diaphragm guide 133, and then the outer surface thereof is supported by the diaphragm guide 133 and the bottom surface is coupled to the upper surface of the diaphragm 131. It comprises a finger 135.

The diaphragm 131 is made of an elastic member having an elastic force to be restored to its original shape when the shape changes. The diaphragm 131 is elastic and the multi-stage cylindrical elastic resistance portion 131a which gradually decreases in diameter to the bottom surface so that the diaphragm 131 becomes convex to the nozzle portion 110 toward the diaphragm 131. A horizontal outer periphery 131b is formed to extend in the horizontal direction along the circumference at the upper end of the resistor portion 131a.

The micro-switch unit 150 has a fixed electrode 152 formed on a bottom surface of the micro switch 150 facing the moving electrode 136, and two switch electrodes connected to the fixed electrode 152 and the moving electrode 136, respectively. 153 is formed to include a switch socket 151, the lower end region including a surface on which the fixed electrode 152 is formed is inserted into the nozzle body body 101 from the top of the nozzle body body 101 is fixed It is composed. In this case, when the fixed electrodes 152 are formed in two and the moving electrode 136 is configured to energize the two fixed electrodes 152, the two switch electrodes 153 are connected to the respective fixed electrodes 152.

When the switch socket 151 is inserted into the inside of the nozzle body 101, the switch socket 151 is pressed against the stepped upper surface of the diaphragm guide 133 supported by the stepped portion formed along the inner diameter surface of the nozzle body 101. Fix it.

The insulation cap 160 is manufactured to have elasticity and insulation characteristics such as silicon and rubber, such that the power switch connected to the switch electrode 153 of the micro switch unit 150 penetrates and is exposed to the outside. The upper portion of the micro switch unit 150 and the nozzle unit is coupled to surround the nozzle unit body 101 to insulate the vacuum switch 100, the outside moisture and foreign matter is introduced into the vacuum switch 100 Is configured to prevent.

By the above-described structure, the vacuum switch 100 of the present invention performs mechanical vacuum switching, not electronic.

The vacuum switch 100 of the present invention having the above-described configuration is mounted at any position of the vacuum flow path by the O-ring 102 so that the region where the microswitch portion 150 is located maintains atmospheric pressure, and the diaphragm portion 130 The lower nozzle body body 101 region turns on / off the vacuum pumps 200, 200a and 200b in accordance with the change of the vacuum pressure inside the brake system while maintaining the negative pressure state by the vacuum.

At this time, by the structural features of the diaphragm 130 as described above, the vacuum switch 100 of the present invention is driven in a double point switching control method to turn on / off the micro switch 150 at different pressures.

At this time, the high pressure value for the deformation of the diaphragm 131 is adjusted by adjusting the position of the screw 112, and the low pressure value is adjusted between the moving electrode 136 and the fixed electrode 152. Adjust by adjusting the interval.

In detail, the elastic resistance part 131a adds a force to the diaphragm 131 so that the diaphragm 131 is convexly deformed into the nozzle part 110. As a result, the diaphragm 131 is convexly shaped toward the microswitch unit 150 in a state where the inside of the nozzle unit 101 has a high air pressure, thereby turning on the microswitch unit 150 to vacuum pumps 200, 200a and 200b. ). On the contrary, when the micro switch unit 150 is turned off, the diaphragm 131 is convex downward when the air pressure inside the nozzle body 101 becomes a negative pressure lower by the force added by the elastic resistance unit 131a. The shape is changed so as to turn off the micro switch 150, thereby stopping the driving of the vacuum pumps 200, 200a, 200b.

As described above, since the on / off of the microswitch unit 150 is performed at different air pressures, the double point switching control method of fundamentally eliminating the occurrence of the chattering is implemented, as well as the vacuum tank 300 (FIG. 1). The interior of the cylinder will always be at a lower pressure.

Therefore, the vacuum switch 100 of the present invention can perform the braking operation a greater number of times compared to the prior art whether the vacuum is restored to an appropriate pressure when the brake operation is performed, thereby significantly improving the safety of the vehicle. .

The configuration and operation characteristics for the double point switching control method of the diaphragm unit 130 will be described in detail with reference to the numerical example of the vacuum pressure.

The air pressure at which the diaphragm 131 is deformed so that the fixed electrode 152 and the moving electrode 136 of the microswitch unit 150 are shorted and the microswitch unit 150 is turned on is set to (600 ± 10) mHg. The air pressure at which the diaphragm 131 is deformed so that the fixed electrode 152 and the moving electrode 136 of the microswitch unit 150 is opened to turn off the microswitch unit 150 is set to (400 ± 10) mHg. As such, it is assumed that the microswitch unit 150 is turned on / off at different air pressures so that the vacuum switch 100 is turned on / off in a double point switching method.

In this case, the internal pressure of the diaphragm 131 in the lower region of the diaphragm 131 by the elastic resistance part 131a, that is, the lower internal region of the nozzle body body 101 on which the spring member 113 is mounted is (600 ± 10). In the case of mHg, the diaphragm 131 is deformed to protrude toward the microswitch unit 150 and the movable electrode 136 is shorted with the fixed electrode 152 so that the microswitch unit 150 is turned on and the vacuum pumps 200 and 200a. , 200b) to perform vacuum.

After the vacuum is performed, the diaphragm 131 is convexly shaped downward when the internal air pressure of the inner lower region of the nozzle body 101 on which the spring member 113 is mounted is (400 ± 10) mHg. By opening the moving electrode 136 from the fixed electrode 152, the micro switch unit 150 is turned off to stop the driving of the vacuum pumps 200, 200a, and 200b.

The deformation of the diaphragm 131 at different air pressures is caused by the elastic resistance portion 131a of the diaphragm 131 adding an elastic force that causes the diaphragm 131 to be convexly deformed into the nozzle 111. And the elastic force acting at the time of the upward convex deformation and downward convex deformation.

The double point switching control method, which is a feature of the present invention, is performed by the shape feature of the diaphragm unit 130.

The present invention can be used with vacuum pumps, such as a dry vacuum pump or a wet vacuum pump.

100: vacuum switch, 101: nozzle body, 102: O-ring, 110: nozzle unit, 111: nozzle
112: screw, 113: spring member,
130: diaphragm portion, 131: diaphragm, 131a: elastic resistance portion, 131b: horizontal outer circumference
133: diaphragm guide, 135: switch finger, 136: moving electrode
150: micro switch portion, 151: switch socket, 152: fixed electrode, 153; Switch electrode
160: insulation cap, 170: power line
200, 200a, 200b: vacuum pump, 210: vacuum pump body
500, 500a, 500b: vacuum pump bracket, 510, 510a, 510b: mounting frame
511, 511a, 511b: mounting holes,
512, 512a, 512b, 513, 513a, 513b: vacuum pump tightening hole
521, 521a, 521b: fixed leg, 522: fixed hole, 523: insertion groove

Claims (11)

delete delete delete delete delete In the vacuum pump for electric vehicles,
Vacuum pump body;
A nozzle unit for applying a negative pressure in the vacuum tank;
A diaphragm portion having an elastic resistance portion for applying a convex deformation force in the direction of the nozzle portion to perform mechanical switching to the micro switch portion according to the height of the air pressure applied by the nozzle portion after being embedded in the nozzle portion; ,
And a micro switch unit which is switched by a mechanical switching action of the diaphragm unit to turn on or off the operation of the vacuum pump.
The diaphragm portion is a vacuum switch configured to be coupled to the vacuum pump body is configured such that the deformation for the on and off of the micro switch unit is performed at different vacuum pressure;
A mounting frame to which the body of the vacuum pump is mounted; and a fixed frame extending perpendicular to a plane formed by the mounting frame at one side of the mounting frame; and one protruding from the fixed frame on the same plane as the fixed frame. Fixed legs above; A vacuum pump bracket configured to fix the vacuum pump to a side surface disposed in parallel with the vacuum pump, including; a vacuum pump for a vehicle brake system, characterized in that formed integrally with the vacuum pump body.
In the vacuum pump for electric vehicles,
A vacuum pump body;
A nozzle unit for applying a negative pressure in the vacuum tank;
A diaphragm portion having an elastic resistance portion for applying a convex deformation force in the direction of the nozzle portion to perform mechanical switching to the micro switch portion according to the height of the air pressure applied by the nozzle portion after being embedded in the nozzle portion; Wow,
And a micro switch unit which is switched by a mechanical switching action of the diaphragm unit to turn on or off the operation of the vacuum pump.
The diaphragm portion is a vacuum switch configured to be coupled to the vacuum pump body is configured such that the deformation for the on and off of the micro switch unit is performed at different vacuum pressure;
And a mounting frame on which the body of the vacuum pump is mounted, and one or more fixed legs extending in the lateral direction of the mounting frame on the same plane as the plane formed by the mounting frame on both sides of the mounting frame. A vacuum pump bracket configured to fix the vacuum pump so that the longitudinal direction of the vacuum pump is in a direction intersecting with the fixed surface on a fixed surface intersecting with the longitudinal direction of the vacuum pump on both sides of the vacuum pump; integrated into the vacuum pump body Vacuum pump for a vehicle brake system, characterized in that formed in.
In the vacuum pump for electric vehicles,
A vacuum pump body;
A nozzle unit for applying a negative pressure in the vacuum tank;
A diaphragm portion having an elastic resistance portion for applying a convex deformation force in the direction of the nozzle portion to perform mechanical switching to the micro switch portion according to the height of the air pressure applied by the nozzle portion after being embedded in the nozzle portion; Wow,
And a micro switch unit which is switched by a mechanical switching action of the diaphragm unit to turn on or off the operation of the vacuum pump.
The diaphragm portion is a vacuum switch configured to be coupled to the vacuum pump body is configured such that the deformation for the on and off of the micro switch unit is performed at different vacuum pressure;
A mounting frame on which the body of the vacuum pump is mounted; and at least one fixed leg extending in a direction perpendicular to a plane formed by the mounting frame at one side of the mounting frame; The vacuum pump bracket for the automobile brake system, characterized in that the vacuum pump bracket for fixing the vacuum pump on the fixed surface disposed in parallel with the longitudinal direction of the vacuum pump is formed integrally with the vacuum pump body.
The method of claim 6, wherein the mounting frame,
A vacuum pump for an automobile brake system, characterized in that it is formed in an annular shape in which a mounting hole into which the vacuum pump body is inserted is formed in the center.
The method according to claim 9, The fixed leg,
And a fixing hole through which a center portion is formed and an insertion groove is open at one side to insert a fixture. The vacuum pump for the automobile brake system of claim 1, further comprising:
delete

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