This application is based upon and claims the benefit of priority from the prior Japanese Patent Applications No. 2013-040766 filed Mar. 1, 2013 and No. 2013-177796 filed Aug. 29, 2013, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a vacuum pump for generating negative pressure to be used in a brake booster of a vehicle such as a car.
2. Related Art
A brake device for car is provided with a brake booster for amplifying a braking force by utilizing negative pressure in an intake pipe (“intake-pipe negative pressure”) of an engine. In recent years, pumping loss is reduced in response to demands for low-fuel consumption and thus the negative pressure in the intake pipe tends to decrease. Furthermore, for a hybrid vehicle, an electric vehicle, or a vehicle with an idling stop function, there is a case where the intake-pipe negative pressure of an engine could not be obtained.
Accordingly, the negative pressure to be supplied to a brake booster is generated by use of an electric vacuum pump. In a vehicle mounting a diesel engine that generates no intake-pipe negative pressure, negative pressure is also generated by use of an electric vacuum pump.
One example of such a vacuum pump is disclosed in, for example, Patent Document 1. In this vane pump, a cam ring and a bearing, which are internally mounted in a casing, are formed with cutouts in alignment with each other on respective outer peripheral surfaces and thus are positioned in place with respect to the casing by a pin inserted in the cutouts. The casing is mounted together with a front cover placed on one end side in a housing placed on the other end side through a joint bolt.
However the vane pump disclosed in Patent Document 1 is configured such that a screw hole for a bolt to integrally assemble the casing and the housing is provided in an annular bracket of a motor. A portion for positioning the cam ring and the baring with respect to the casing and a portion through which the bolt is formed to integrally assemble the casing and the housing are formed in different positions so that they are displaced in a radial direction of the vane pump. This causes an increase in cross sectional area of the vane pump in the radial direction, resulting in a large sized vane pump.
The present invention has been made to solve the above problems and has a purpose to provide an electric vacuum pump capable of achieving reduced size and improved accuracy of assembling components to constitute a pump chamber.
To achieve the above purpose, one aspect of the invention provides an electric vacuum pump including: a case having internal space; a motor part placed in the internal space of the case; and a pump part placed in the internal space of the case and to be driven in sync with the motor part, wherein the pump part includes: a cylindrical pump housing; a first cover member placed in the pump housing on one end side in a center axis direction of the pump housing; a second cover member placed in the pump housing on the other end in the center axis direction; a pump chamber formed by an inner peripheral surface of the pump housing, the first cover member, and the second cover member; and a rotor housed in the pump chamber and including a plurality of vanes inserted therein, the electric vacuum pump further includes a fastening member passed through a through hole formed in the first cover member and being fastened in a fastening hole formed in the case to fix the first cover member to the case and the pump housing, the pump housing is provided with a positioning retainer formed on an outer periphery and the second cover member is provided with a positioning retainer formed on an outer periphery, the case is provided with a positioning protrusion formed to protrude inward from an inner peripheral surface of the case, the positioning retainers are in contact with the positioning protrusion to position the pump housing and the second cover member with respect to the case, and the fastening hole is formed in the positioning protrusion.
According to the above configuration, the first cover member is fixed to the case and the pump housing by the fastening member. The fastening hole in which the fastening member is to be fastened is formed in the positioning protrusion formed on the inner peripheral surface of the case. In this way, the positioning protrusion and the fastening hole are formed in the same place in the radial direction. Accordingly, the cross sectional area of the electric vacuum pump in the radial direction is reduced and thus the electric vacuum pump can be reduced in size. When the positioning retainers are in contact with the positioning protrusion, positioning the pump housing and the second cover member with respect to the case, the pump housing and the second cover member can be assembled with the case with high accuracy. In this manner, the electric vacuum pump can achieve size reduction and also improved assembling accuracy of the components to form the pump chamber.
The pump housing and the second cover member are placed in contact with the case so that the positioning retainers contact with the positioning protrusion. This can enhance heat dissipation property of the electric vacuum pump from the pump part to the outside.
In the above configuration, preferably, the positioning retainers are formed to respectively protrude from an outer peripheral surface of the pump housing and an outer peripheral surface of the second cover member toward the inner peripheral surface of the case and include grooves engageable with the positioning protrusion.
According to the above configuration, the grooves of the positioning retainer is in contact engagement with the positioning protrusion of the case, thereby enabling reliable positioning of each of the pump housing and the second cover member with respect to the case. This further improves the assembling accuracy of the pump housing and the second cover member with respect to the case.
In the above configuration, preferably, the case has an end face on the one end side in the center axis direction of the pump housing, the end face being located in the same position as an end face of the first cover member on the other end side in the center axis direction of the pump housing or located in a position closer to the one end side than the end face of the first cover member on the other end side.
According to the above configuration, a portion of the positioning protrusion surrounding the fastening hole in the radial direction can have sufficient thickness and also the outer peripheral surface of the case and the outer peripheral surface of the positioning protrusion can be made common. This enables further reduction in the cross sectional area of the case in the radial direction and thus further size reduction of the electric vacuum pump.
In the above configuration, preferably, the pump part and the inner peripheral surface of the case form therebetween a space in an area excepting the positioning protrusion and the positioning retainers.
According to the above configuration, the space is generated around the pump part. Since the fastening hole is formed in the positioning protrusion as above, the volume of the space can be increased as large as possible. This can enhance the silencing performance of the electric vacuum pump during operation.
Preferably, the above configuration further includes a member placed in the space to produce at least one of a silencing effect and a cooling effect.
According to the above configuration, the silencing performance and the cooling performance of the electric vacuum pump can be further enhanced. Since the member is set in the space formed between the pump part and the inner peripheral surface of the case, furthermore, assembling the member is easy.
In the above configuration, preferably, the case includes a rib placed in the space and formed to protrude inward from the inner peripheral surface of the case.
According to the above configuration, the case can have high strength.
In the above configuration, preferably, the case is provided with a plurality of the positioning protrusions and a plurality of the fastening holes in two or more and odd-numbered pairs, and one pair of the pairs of positioning protrusions and fastening holes is placed in a position 180° opposite to a center axis of the inner peripheral surface of the pump housing with respect to a rotation center axis of the rotor.
According to the above configuration, the electric vacuum pump can be reduced in size more effectively.
In the above configuration, preferably, the first cover member includes a suction inlet for sucking gas from outside into the pump chamber and a discharge outlet for discharging gas from the pump chamber to the outside, and the pump housing and the first cover member are integrally formed.
The above configuration can provide improved positional accuracy of the suction inlet for sucking gas from outside into the pump chamber and the discharge outlet for discharging gas from the pump chamber to the outside, thus increasing a pump efficiency of the electric vacuum pump.
In the above configuration, preferably, a cover closing the internal space of the case from a side of the pump part, and the cover and the first cover member form therebetween a space.
According to the above configuration, the space is formed in the cover member and thus the silencing performance of the electric vacuum pump during operation can be enhanced.
In the above configuration, preferably, the pump housing has a cylindrical shape of which the outer peripheral surface has a polygonal cross section, the second cover member has a plate-like shape of which the outer peripheral surface has a polygonal cross section, and each of the positioning retainers is a surface defined by a side of the polygonal cross section.
According to the above configuration, the surface defined by one side of the polygonal shape of each of the pump housing and the second cover member is placed in contact with the positioning protrusion of the case, so that the pump housing and the second cover member can be reliably positioned in place with respect to the case. Accordingly, the assembling accuracy of the pump housing and the second cover member with respect to the case can be further improved.
In the above configuration, preferably, the case is made of a metal material.
The above configuration allows the pump housing and the second cover member to be press-fit in the metal case, so that the accuracy for assembling the member to constitute the pump chamber in the radial direction can be enhanced.
The electric vacuum pump according to the invention can achieve reduced size and improved accuracy for assembling components to constitute a pump chamber.
A detailed description of a preferred embodiment of an electric vacuum pump embodying the present invention will now be given referring to the accompanying drawings. In the present embodiment, the electric vacuum pump of the invention applied to a brake system will be explained.
This brake system is first explained referring to
A brake system 1 in the present embodiment includes, as shown in
The brake booster 12 is provided between the brake pedal 10 and the master cylinder 14 as shown in
The brake booster 12 is internally partitioned by a diaphragm (not illustrated) into a negative pressure chamber (not shown) close to the master cylinder 14 and a transformer chamber (not shown) allowing introduction of atmospheric air. The negative pressure chamber of the brake booster 12 is connected to an intake pipe 32 of an engine through a first passage L1. Specifically, the first passage L1 is connected to the negative pressure chamber of the brake booster 12 and the intake pipe 32. Accordingly, the negative pressure chamber of the brake booster 12 is supplied with negative pressure generated in the intake pipe 32 through the first passage L1 according to an opening degree of a throttle valve 34 during driving of the engine.
The master cylinder 14 increases oil pressure of a brake main body (not shown) by operation of the brake booster 12, thereby generating a braking force in the brake main body. The negative pressure sensor 16 detects the negative pressure in the negative pressure chamber of the brake booster 12.
The electric vacuum pump 18 is connected to a second passage L2 as shown in
The electric vacuum pump 18 is further connected to the ECU 24 through a relay 36 as shown in
The first check valve 20 is provided in the first passage L1 at a position between a branch point to the second passage L2 and the brake booster 12 as shown in
The ECU 24 consists of for example a microcomputer and includes a ROM that stores control programs, a rewritable RAM that stores calculation results and others, a timer, a counter, an input interface, and an output interface. To this ECU 24, as shown in
Next, the electric vacuum pump 18 will be explained referring to
The electric vacuum pump 18 has a cylindrical shape as shown in
The motor part 110 includes an electric motor 112, a metal motor case 114, a rotary shaft 116, and the connector 118. The electric motor 112 is set in the motor case 114 and includes a stator 112a and a rotor 112b. The stator 112a is fixed to the motor case 114 so that the rotor 112b is rotatably placed inside the stator 112a with a clearance therefrom.
The rotary shaft 116 is attached to this rotor 112b. The connector 118 including terminals 118a for supplying electric power to the electric motor 112 (the stator 112a) is provided on the lower cover 160.
Accordingly, in the motor part 110, the electric motor 112 is driven by an external power supply connected through the connector 118 to drive the rotary shaft 116 to rotate. The rotary shaft 116 is rotatably supported by a bearing fixed to the motor case 114.
The pump part 120 is constituted of a vane-type vacuum pump and is placed above the motor part 110 in the case 130. The pump part 120 will be driven in sync with the motor part 110. Herein, the vane-type vacuum pump is configured such that a rotor having a circular columnar shape placed in an eccentric state in a pump chamber is formed with grooves, in which a plurality of vanes are inserted to be movable in a rotor radial direction. When the rotor rotates, the vanes are caused to protrude from the grooves by centrifugal force and slide in contact with the inner peripheral surface of the pump chamber, thereby maintaining hermetical sealing between adjacent small chambers of the pump chamber. In association therewith, the volume of each closed space or small chamber partitioned by the vanes is increased or decreased, thereby causing suction, compression, and discharge of air, so that negative pressure is generated in the pump chamber.
To be concrete, the pump part 120 is provided with a pump housing 121 having an inner peripheral surface 121a of a nearly cylindrical shape. The inner peripheral surface 121a of a nearly cylindrical shape represents that the cross section of the pump housing is defined in a circular shape surrounded by a curved line without being limited to a perfect circular or elliptic shape. Both ends of the pump housing 121 are closed by an upper-end cover member 122a (see
In the pump chamber 123, a circular columnar rotor 124 is housed to be rotatable about the axis eccentric to the center axis of the pump chamber 123. This rotor 124 is coupled to the rotary shaft 116 of the electric motor 112. Accordingly, the rotor 124 is rotated in sync with rotary driving of the electric motor 112 via the rotary shaft 116.
The rotor 124 has a plurality of vane grooves. In the vane groove, vanes 125 each formed in a flat plate shape are slidably engaged to be radially movable in and out. A radially outer end of each vane 125 slides in contact with the inner peripheral surface 121a of the pump housing 121 by centrifugal force imparted to the vanes 125 during rotation of the rotor 124. Upper and lower end faces of the vanes 125 are in contact with the cover members 122a and 122b respectively. Thus, the vanes 125 partition the pump chamber 123 into a plurality of small chambers or spaces.
The pump chamber 123 communicates with the outside through a suction inlet 126 and a discharge outlet 127. The suction inlet 126 is provided in the upper-end cover member 122a to communicate with the pump chamber 123. The suction inlet 126 is hermetically connected to an inlet pipe 141a continuous with the suction port 141 to suck air from pump outside into the pump chamber 123. Similarly, the discharge outlet 127 is also provided in the upper-end cover member 122a to communicate with the pump chamber 123. Exhaust air ejected from the discharge outlet 127 is discharged to the pump outside through the discharge port 142.
The upper cover 140 is a resin member closing an upper open end of the case 130 accommodating the motor part 110 and the pump part 120. The upper cover 140 is one example of a “cover” of the invention. Specifically, the upper cover 140 closes the case 130 from the pump part side (from above in
This upper cover 140 is provided with the suction port 141 to suck air in the pump part 120 from the pump outside, the inlet pipe 141a connected to the suction port 141, a silencer part 143 formed by the space communicating with the discharge outlet 127 of the pump part 120, the discharge port 142 to discharge exhaust air discharged or ejected from the pump part 120 to the pump outside, and a throat part 142a provided in the discharge port 142.
The silencer part 143 is formed by the internal space of the upper cover 140. Specifically, the silencer part 143 is defined by the space between the upper cover 140 and the upper-end cover member 122a. The throat part 142a is formed in the discharge port 142. Thus, exhaust air discharged or ejected from the discharge outlet 127 of the pump part 120 passes through the silencer part 143 and then is discharged to the pump outside through the throat part 142a. Consequently, the exhaust air can be repeatedly exposed to loads, so that pump operation sound or noise can be reduced to a minimum. In this manner, the electric vacuum pump 18 can be effectively provided with the sound-reducing (silencing) measure with a very simple structure.
The shape of the throat part 142a is not particularly limited and may be a shape that an entire discharge port is narrowed to form a throat as shown in
The lower cover 160 is a resin member closing a lower open end of the case 130 accommodating the motor part 110 and the pump part 120. The lower cover 160 closes the case 130 from the motor part side (from below in
In the electric vacuum pump 18 configured as above, when the electric motor 112 is driven to rotate upon receipt of power from an external source, the rotor 124 is rotated in synchronization therewith. Then, the vanes 125 slide along the vane grooves by centrifugal force, causing the end faces of the vanes 125 to contact with the inner peripheral surface 121a of the pump housing 121. While keeping such a contact state, the vanes 125 are rotated along the inner peripheral surface 121a of the pump housing 121. This rotation of the rotor 124 causes the volume of each small chamber of the pump chamber 123 to expand or contract, thereby sucking air into the pump chamber 123 through the suction inlet 126 and ejecting air from the pump chamber 123 through the discharge outlet 127. This operation generates negative pressure in the pump chamber 123.
Specifically, in the brake system 1, when the relay 36 is turned on based on a drive start signal from the ECU 24, the electric vacuum pump 18 starts operating, thereby supplying negative pressure to the negative pressure chamber of the brake booster 12 through the suction port 141, the second passage L2 and the first passage L1. Furthermore, when the relay 36 is turned off based on a drive stop signal from the ECU 24, the electric vacuum pump 18 stops operating, thereby stopping supplying negative pressure to the negative pressure chamber of the brake booster 12 through the suction port 141, the second passage L2 and the first passage L1.
In the brake system 1, in a case where the engine is running and negative pressure is generated in the intake pipe, the negative pressure in the intake pipe 32 is supplied to the negative pressure chamber of the brake booster 12 through the first passage L1 to regulate the negative pressure in the negative pressure chamber of the brake booster 12. In a case where the engine is stopped or in a case where the ECU 24 determines that the negative pressure is insufficient, the ECU 24 turns on the relay 36, thereby driving the electric vacuum pump 18 to supply the negative pressure to the negative pressure chamber of the brake booster 12 through the second passage L2 and the first passage L1. Thus, the negative pressure in the negative pressure chamber of the brake booster 12 can be regulated.
Herein, an explanation is given to positioning of the pump housing 121 and the lower-end cover member 122b with respect to the case 130 and fixing of the upper-end cover member 122a to the pump housing 121 and the case 130.
As shown in
In the present embodiment, as shown in
The case 130 is provided, on its inner peripheral surface 130a, with positioning protrusions 176 formed radially protruding inward in the case 130. Each of the positioning protrusions 176 is designed so that its outer peripheral surface 176a has a nearly cylindrical shape. The positioning protrusions 176 are arranged outside the pump chamber 123 in the radial direction of the case 130. In an example shown in
As shown in
As shown in
As shown in
In the present embodiment, the screw holes 174 are formed one each in the positioning protrusions 176. In this way, the screw holes 174 and the positioning protrusions 176 are arranged in the same positions in the radial direction of the case 130. Thus, the cross sectional area of the electric vacuum pump 18 in the radial direction is small and the electric vacuum pump 18 can be reduced in size.
In the present embodiment, as shown in
In the above manner, while each portion forming the positioning protrusions 176 surrounding the corresponding screw holes 174 in the radial direction is thick enough to resist against fastening forces of the screws 170, an outer peripheral surface 130c of the case 130 and outer peripheral surfaces 176a of the positioning protrusions 176 are made common. This can achieve reduction of the cross sectional area of the case 130 in the radial direction and further size reduction of the electric vacuum pump 18.
The inner peripheral surface 130a of the case 130 is located outside the outer peripheral surface 122aa of the upper-end cover member 122a, so that the upper-end cover member 122a is assembled with the pump housing 121 by being guided by the inner peripheral surface 130a of the case 130. Thus, the assembling accuracy of the upper-end cover member 122a (positional accuracy of the upper-end cover member 122a to be assembled) in the radial direction (a right and left direction in
In the axial direction of the electric vacuum pump 18, the upper end face 130b of the case 130 may be located on the same level or position as the lower end face 122ab of the upper-end cover member 122a.
Silencer parts 186 are formed by space or cavity between the pump part 120 and the inner peripheral surface 130a of the case 130, in an area excepting the positioning protrusions 176, positioning retainers 178, and positioning retainers 182. Each silencer part 186 is communicated with the aforementioned silencer part 143. In the present embodiment in which the screw holes 174 are formed in the positioning protrusions 176, the width δ (see
In a modified example, as shown in
As shown in
As another modified example, as shown in
As another modified example, the case 130 may be made of metal. As shown in
The electric vacuum pump 18 in the present embodiment explained in detail above includes the case 130 having the internal space, the motor part 110 placed in the internal space of the case 130, and the pump part 120 placed in the internal space of the case 130 and to be driven in sync with the motor part 110. The pump part 120 includes the cylindrical pump housing 121, the upper-end cover member 122a placed on the upper end of the pump housing 121 in the center axis direction thereof, the lower-end cover member 122b placed on the lower end of the pump housing 121 in the center axis direction thereof, the pump chamber 123 formed by the inner peripheral surface 121a of the pump housing 121, the upper-end cover member 122a, and the lower-end cover member 122b, and the rotor 124 which is set in the pump chamber 123 and in which the plurality of vanes 125 are inserted. The screws 170 are passed through the through holes 172 of the upper-end cover member 122a and fastened in the screw holes 174 of the case 130, thereby fixing the upper-end cover member 122a to the case 130 and the pump housing 121. The pump housing 121 includes the positioning retainers 178 formed on the outer periphery of the pump housing 121. The lower-end cover member 122b includes the positioning retainers 182 formed on the outer periphery of the lower-end cover member 122b. The case 130 includes the positioning protrusions 176 formed to protrude inward in the case 130 from the inner peripheral surface 130a of the case 130. Since the positioning retainers 178 and the positioning retainers 182 are in contact with the positioning protrusions 176, the pump housing 121 and the lower-end cover member 122b are positioned in place with respect to the case 130. The positioning protrusions 176 are formed with the screw holes 174.
As above, the screw holes 174 are formed in the positioning protrusions 176 of the case 130. The positioning protrusions 176 and the corresponding screw holes 174 are thus formed in the same places in the radial direction, so that the electric vacuum pump 18 can have a reduced cross sectional area in the radial direction and thus can have a reduced size. Since the positioning retainers 178 and the positioning retainers 182 are in contact with the positioning protrusions 176, thereby positioning the pump housing 121 and the lower-end cover member 122b with respect to the case 130, the assembling accuracy of the pump housing 121 and the lower-end cover member 122b with respect to the case 130 can be enhanced. In the above manner, the electric vacuum pump 18 can achieve size reduction and improved assembling accuracy of the components to form the pump chamber 123.
The pump housing 121 and the lower-end cover member 122b are in contact with the case 130 in such a manner that the positioning retainers 178 and the positioning retainers 182 contact with the positioning protrusions 176. This can improve heat dissipation performance of the electric vacuum pump 18 from the pump part 120 to the outside.
The positioning retainers 178 and the positioning retainers 182 are respectively formed to protrude from the outer peripheral surface 121b of the pump housing 121 and the outer peripheral surface 122ba of the lower-end cover member 122b toward the inner peripheral surface 130a of the case 130 and also respectively include the grooves 180 and the grooves 184 engageable with the positioning protrusions 176. Accordingly, the grooves 180 and the grooves 184 are in contact engagement with the positioning protrusions 176, thereby ensuring positioning of the pump housing 121 and the lower-end cover member 122b with respect to the case 130. Therefore, the assembling accuracy of the pump housing 121 and the lower-end cover member 122b with respect to the case 130 can be further improved.
In the center axis direction of the pump housing 121, the upper end face 130b of the case 130 is located on the same level or position as the lower end face 122ab of the upper-end cover member 122a or located above the lower end face 122ab of the upper-end cover member 122a. Accordingly, while ensuring the sufficient thickness of the portion of each positioning protrusion 176 surrounding the screw hole 174 in the radial direction, the outer peripheral surface 130c of the case 130 and the outer peripheral surface 176a of each positioning protrusion 176 are made common. This can achieve further reduction of the cross sectional area of the case 130 in the radial direction and thus further size reduction of the electric vacuum pump 18.
The electric vacuum pump 18 is provided with the silencer parts 186 between the pump part 120 and the inner peripheral surface 130a of the case 130, in the area excepting the positioning protrusions 176 and the positioning retainers 178 and 182. Thus, the silencer parts 186 are formed around the pump part 120. Since the positioning protrusions 176 are formed with the screw holes 174 as above, the volume of the silencer parts 186 can be increased as much as possible. This can enhance the silencing performance of the electric vacuum pump 18 during operation.
In the silencer parts 186, there may be placed the filters 194 that exert at least one of the silencing effect and the cooling effect. Accordingly, the silencing performance and the cooling performance of the electric vacuum pump 18 can be further improved. The filters 194 are simply set in the silencer parts 186 defined by the pump part 120 and the inner peripheral surface 130a of the case 130, so that assembling the filters 194 are easy.
The electric vacuum pump 18 may further include the ribs 196 formed in the silencer parts 186 to protrude radially inward from the inner peripheral surface 130a of the case 130. This can enhance the strength of the case 130.
The pairs of the positioning protrusions 176 and the screw holes 174 are formed as two or more and odd-numbered pairs so that one pair of the pairs of the positioning protrusions 176 and the screw holes 174 is placed in a position 180° opposite to the center axis Sp of the inner peripheral surface 121a of the pump housing 121 with respect to the rotation center axis Sr of the rotor 124. This can effectively achieve size reduction of the electric vacuum pump 18.
The electric vacuum pump 18 further includes the upper cover 140 that closes the internal space of the case 130 from the side of the pump part 120. Between the upper cover 140 and the upper-end cover member 122a, the silencer part 143 is formed. Since the space is thus generated in the upper cover 140, the electric vacuum pump 18 can provide improved silencing performance during operation.
In a case where the case 130 is made of metal, the pump housing 121 and the lower-end cover member 122b can be press-fitted in the metal case 130. Thus, the components to form the pump chamber 123 can be assembled with high accuracy in the radial direction of the pump housing 121.
A conceivable modified example is shown in
Further, a modified example shown in
The aforementioned embodiment and examples are mere examples and do not limit the invention. The present invention may be embodied in other specific forms without departing from the essential characteristics thereof.
Number | Date | Country | Kind |
---|---|---|---|
2013-040766 | Mar 2013 | JP | national |
2013-177796 | Aug 2013 | JP | national |