WO2017188128A1

WO2017188128A1 - Negative pressure type boosting device

Info

Publication number: WO2017188128A1
Application number: PCT/JP2017/015949
Authority: WO
Inventors: 優一榊原
Original assignee: 株式会社アドヴィックス
Priority date: 2016-04-28
Filing date: 2017-04-20
Publication date: 2017-11-02
Also published as: JP2017197064A

Abstract

In the present invention, at least one of one shell 21, another shell 22, and a movable partition wall 3 is provided with: a radial center section 313 formed on an annular one end surface 311, which is an end surface on one side in the axial direction; and a plurality of protrusion sections 314 protruding from the one end surface 311 in the axial direction. When viewed from the axial direction, the plurality of protrusion sections 314 extend in a radial manner from the radial center section 313, and at least one of the plurality of protrusion sections 314 has, in at least a radially outward end section of the one end surface 311, a curved region 314a or a straight region 314b which extends in a direction that intersects the radial direction and the circumferential direction of the one end surface 311.

Description

Negative pressure booster

This invention relates to the negative pressure type booster mainly applied to a brake device.

The negative pressure booster includes, for example, a housing composed of a front shell and a rear shell, a movable partition that divides the housing into a front negative pressure chamber and a rear variable chamber, and the variable pressure chamber with respect to the atmosphere. And a main body part to be opened or closed. When the variable pressure chamber is opened to the atmosphere, the movable partition is pushed forward toward the negative pressure chamber by the differential pressure between the variable pressure chamber and the negative pressure chamber. Such a negative pressure booster is described in, for example, Japanese Patent Application Laid-Open No. 2007-076437. Here, the front shell or the like provided with radial ribs is described.

JP 2007-076437 A

Here, in a general radial rib, each rib is formed along the radial direction of a shell or the like. For this reason, the magnitude of the rigidity is generated with respect to the direction of the stress to be received, and sufficient rigidity may not always be exhibited. For example, any stress is easily applied to the outer peripheral edge of the shell or the like, and other reinforcing parts are required when the outer peripheral edge is formed of resin or the like.
This invention is made | formed in view of such a situation, and it aims at providing the negative pressure type booster which can adjust the direction of reinforcement | strengthening especially in the outer periphery part of an object member.

The negative pressure type booster of the present invention includes a housing having one shell constituting a portion on one side in the axial direction and the other shell disposed on the other side in the axial direction of the one shell; A movable partition wall that is divided into a negative pressure chamber on one side of the direction and a variable pressure chamber on the other side of the axial direction and movable in the axial direction, and a main body portion that communicates and blocks between the variable pressure chamber and the atmosphere. The at least one of the one shell, the other shell, and the movable partition wall is a radiation center formed on an annular one end surface that is one end surface in the axial direction. And a plurality of protrusions protruding in the axial direction from the one end surface, and when viewed from the axial direction, the plurality of protrusions extend radially from the radiation center, Small number of protrusions Both one is at least at the radially outer end of said one end face has the other hand extend in a direction crossing the radial direction and the circumferential direction of the end face curvilinear portions or straight portions.

According to the present invention, at least the radially outer end of the target member (one shell, the other shell, and the movable partition wall), the extending direction of the protruding portion intersects the radial direction of the one end surface. Yes. Thereby, the rigidity of directions other than the radial direction of an object member is strengthened. That is, it is possible to adjust the directionality of reinforcement at least at the radially outer end (outer peripheral edge) of the target member.

It is sectional drawing which shows the structure of the negative pressure type booster of 1st embodiment. It is sectional drawing which shows the structure of the main-body part of 1st embodiment. It is the block diagram seen from the front which shows the plate of 1st embodiment. It is the block diagram seen from the front which shows the plate of 2nd embodiment. It is the block diagram seen from the front which shows the plate of 3rd embodiment. It is a perspective view which shows the plate of 3rd embodiment. It is the block diagram seen from the front which shows the plate of 4th embodiment. It is the block diagram seen from the front which shows the plate of 5th embodiment. It is the block diagram seen from the front which shows the plate of 6th embodiment. It is the block diagram seen from the front which shows the plate of 7th embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, the same or equivalent parts are denoted by the same reference numerals in the drawings. Each figure used for explanation is a conceptual diagram, and the shape of each part may not necessarily be exact. In the embodiment, a description will be given based on a state in which the negative pressure booster is arranged in the vehicle, the front means the front of the vehicle, and the rear means the rear of the vehicle. “Front” can be replaced with “one” and “back” can be replaced with “other”. In this embodiment, when the moving direction of the movable partition 3 is an axial direction, the front corresponds to one of the axial directions, and the rear corresponds to the other of the axial directions.

<First embodiment>
As shown in FIG. 1, the negative pressure booster 1 includes a housing 2, a movable partition wall 3, and a main body 4. The housing 2 includes a front shell (corresponding to “one shell”) 21 constituting a front portion, and a rear shell (corresponding to “other shell”) 22 disposed on the rear side of the front shell 21. Have. The housing 2 is a cylindrical hollow member, and is configured by fixing a rear end portion of the front shell 21 and a front end portion of the rear shell 22. The front shell 21 is a cylindrical member and is made of resin. The front shell 21 includes an annular bottom surface portion 211 and a cylindrical side surface portion 212. The annular bottom surface portion 211 and the cylindrical side surface portion 212 are integrally formed.

The annular bottom surface portion 211 is a front end portion of the front shell 21 formed in an annular shape. A master cylinder (not shown) is assembled in an airtight manner to the inner peripheral portion 211 a at the center of the annular bottom surface portion 211. The annular bottom surface portion 211 has a negative pressure introducing portion (not shown) for connecting a connecting pipe (not shown) connected to a negative pressure source (for example, an intake manifold of the engine) and a negative pressure chamber R1 described later. ) Is formed. This negative pressure introducing portion is provided with a check valve mechanism. The cylindrical side surface portion 212 has a cylindrical shape and is formed so as to protrude rearward from the outer peripheral portion of the annular bottom surface portion 211. A diameter-expanded portion 212 a to which the rear shell 22 and a bead portion 32 described later are assembled and fixed is formed at the rear end portion of the cylindrical side surface portion 212. Although not shown, a plurality of annular concentric ribs and radial radial ribs that intersect with each other are formed on the rear end surface of the annular bottom surface portion 211.

The rear shell 22 is a cylindrical member and is made of resin. The rear shell 22 includes an annular bottom surface portion 221 and a cylindrical side surface portion 222. The annular bottom surface portion 221 and the cylindrical side surface portion 222 are integrally formed. The annular bottom surface portion 221 is a rear end portion of the rear shell 22 formed in an annular shape. A valve body 41, which will be described later, is assembled to the inner peripheral portion 221a at the center of the annular bottom surface portion 221 so as to be able to advance and retract (movable in the front-rear direction). The cylindrical side surface portion 222 has a columnar shape and is formed so as to protrude forward from the outer peripheral portion of the annular bottom surface portion 221. A protruding portion 222 a that protrudes radially outward from the outer peripheral surface is formed at the front end portion of the cylindrical side surface portion 222. The rear shell 22 is airtightly assembled to the front shell 21 so that the bead portion 32 is sandwiched between the front portion of the protruding portion 222a and the enlarged diameter portion 212a. A plurality of concentric ribs and radiation ribs (not shown) are formed on the rear end surface 221b of the annular bottom surface portion 221.

The movable partition wall 3 is a part that divides the interior of the housing 2 into a negative pressure chamber R1 on the front side and a variable pressure chamber R2 on the rear side. The movable partition 3 includes an annular plate 31 and an annular diaphragm 32 connected to the rear surface of the plate 31. The movable partition wall 3 is installed in the housing 2 so as to be movable in the front-rear direction (the axial direction of the power piston 40). The plate 31 is a resin member and has a smaller diameter than the rear shell 22. The diaphragm 32 is airtightly sandwiched between the housing 2 by an annular outer peripheral bead portion 32a formed on the outer peripheral edge thereof. The diaphragm 32 is airtightly fixed to the outer peripheral portion of the valve body 41 by an annular inner peripheral bead portion 32b formed on the inner peripheral edge thereof. Details of the plate 31 will be described later. In this embodiment, a tie rod type is adopted, and an assembly part T into which the tie rod 8 is inserted in an airtight manner and assembled is formed in each of the housing 2 and the movable partition wall 3. The movable partition wall 3 is configured to be able to advance and retract in an airtight manner with respect to the tie rod 8.

The main body 4 is a member that communicates and blocks between the variable pressure chamber R2 and the atmosphere. In other words, the main body 4 is a mechanism that opens or closes the variable pressure chamber R2 with respect to the atmosphere. Specifically, as shown in FIGS. 1 and 2, the main body 4 mainly includes a valve body 41, an input member 42, a negative pressure valve V1, and an atmospheric valve V2.

The valve body 41 is a resin hollow body connected to the inner periphery of the movable partition wall 3. The valve body 41 as a whole is formed in a cylindrical shape whose front-rear direction is the axial direction. The valve body 41 is assembled to the rear shell 22 of the housing 2 so as to be airtight and movable in the front-rear direction. The valve body 41 is urged rearward by a return spring 23 interposed between the valve body 41 and the front shell 21.

A step A is provided on the inner peripheral surface of the valve body 41 so that the inner diameter of the rear part is larger than the inner diameter of the central part. In other words, the valve body 41 is formed with a stepped passage 41a extending in the front-rear direction by the inner peripheral surface thereof. The inner peripheral surface (rear end portion of the passage 41a) of the rear portion of the valve body 41 constitutes an air introduction passage 41a1 that connects a later-described vent hole 19a and the air valve V2. The air introduction path 41a1 is a flow path that connects the atmosphere (outside air) and the atmosphere valve V2 through the vent hole 19a.

Also, a pair of negative pressure communication passages 41b (only one is shown in the figure) is formed inside the valve body 41. In other words, a cylindrical negative pressure communication path 41 b that is a flow path extending in the front-rear direction is provided inside the valve body 41. The negative pressure communication path 41b is a flow path whose rear end opens to the atmosphere introduction path 41a1 and whose front end opens to the negative pressure chamber R1. A filter 5 is disposed at the rear end of the air introduction path 41a1.

The portion of the valve body 41 arranged outside the housing 2 is covered with the boot 19. The boot 19 is a rubber covering member having a bellows-shaped front part 191 and a rear part 192. The front end portion of the front portion 191 is engaged with the rear end portion of the rear shell 22 (the inner peripheral portion 221a of the annular bottom surface portion 221). The rear portion 192 is formed integrally with the rear end portion of the front portion 191, and is disposed at the rear end portion of the valve body 41 so as to close the rear end opening of the valve body 41. The rear part 192 is provided with a plurality of vent holes 19a.

The input member 42 is a shaft-like member that moves forward in response to a brake operation. Specifically, the input member 42 includes a shaft member 421 and a plunger (air valve) 422. The shaft member 421 and the plunger 422 are coaxially assembled to the passage 41a. As shown in FIG. 1, a connecting member 423, a reaction member 424, and an output shaft (output member) 425 are coaxially assembled with respect to the passage 41a in front of the plunger 422. The shaft member 421 can advance and retract with respect to the valve body 41. The shaft member 421 is articulated to the receiving connection portion 422c of the plunger 422 at the spherical tip portion 421a.

The shaft member 421 is connected to a brake pedal (not shown) via a yoke at the rear end screw portion. The shaft member 421 moves forward according to the operation of the brake pedal. It can be said that the shaft member 421 is an input shaft for inputting a pedaling force to the master cylinder. The shaft member 421 is engaged with the return spring 427 via the retainer 426 locked to the intermediate step A of the passage 41a, and is urged rearward by the return spring 427. The plunger 422 connected to the shaft member 421 is also urged rearward by the return spring 427. The retainer 426 is a cylindrical member provided to the shaft member 421 coaxially with the shaft member 421. The retainer 426 has a function of returning the shaft member 421 to the initial position.

The plunger 422 is disposed in the valve body 41 (passage 41a), is a member that can move forward and backward in the axial direction of the passage 41a with respect to the valve body 41 and moves integrally with the shaft member 421. The plunger 422 functions as an air valve. The plunger 422 is arranged so that the front end portion thereof can come into contact with the rear surface central portion of the reaction member 424 via the connecting member 423. The front end portion of the plunger 422 is a portion that partially receives the reaction force from the reaction member 424 with respect to the output via the connecting member 423. An annular groove 422b is formed at an intermediate portion of the plunger 422. The annular groove 422b is formed to be engageable with the key member 429. An annular atmospheric valve seat 422d constituting the atmospheric valve V2 is formed at the rear end portion of the plunger 422. The output shaft 425 is assembled to the front end portion of the passage 41a of the valve body 41 together with the reaction member 424 so as to be movable in the front-rear direction. The distal end portion of the output shaft 425 is in contact with an engaging portion (concave portion) of the piston in the master cylinder 9 so as to be able to be pushed. The output shaft 425 transmits the reaction force received from the piston of the master cylinder 9 to the reaction member 424 during the braking operation.

The negative pressure valve V1 is a valve mechanism that communicates and blocks between the negative pressure chamber R1 and the variable pressure chamber R2 in accordance with the advancement and retreat of the plunger 422 with respect to the valve body 41. In other words, the negative pressure valve V1 communicates and blocks between the negative pressure chamber R1 and the variable pressure chamber R2 according to the relative positions of the valve body 41 and the shaft member 421 (input member 42). The negative pressure valve V1 includes a negative pressure valve portion 61b1 and a negative pressure valve seat 41d. The negative pressure valve portion 61 b 1 is a part of the valve body 61 disposed in the valve body 41. The valve body 61 is a cylindrical member as a whole disposed in the passage 41a. The valve body 61 connects the fixed portion 61a assembled to the inner peripheral surface of the valve body 41, the movable portion 61b that can move relative to the fixed portion 61a in the axial direction, and the fixed portion 61a and the movable portion 61b. 61d. The movable portion 61b is disposed on the front side of the fixed portion 61a. The movable portion 61 b is urged forward by the compression spring 63. The compression spring 63 is a compressed spring whose front end is in contact with the movable portion 61b and whose rear end is in contact (engagement) with the shaft member 421, and is formed to have a smaller diameter toward the rear end. . The outer peripheral side of the front end portion of the movable portion 61b constitutes the negative pressure valve portion 61b1. In other words, the negative pressure valve portion 61b1 is formed at the front end portion of the movable portion 61b. The movable portion 61b is composed of an elastic movable portion 61e made of an elastic material and a metal movable portion 61f formed in an annular plate shape made of a metal material fixed to the rear surface of the elastic movable portion 61e. . The elastic movable part 61e is integrally connected to the connecting part 61d.

The negative pressure valve seat 41d is formed at the rear end of the negative pressure communication passage 41b. In other words, the rear end portion of the negative pressure communication passage 41b constitutes the negative pressure valve seat 41d. The state in which the negative pressure valve portion 61b1 is in contact (sitting) with the negative pressure valve seat 41d means that the negative pressure valve V1 is closed, and the state in which the negative pressure valve portion 61b1 is separated (separated) from the negative pressure valve seat 41d is the opening of the negative pressure valve V1. Means (open).

The atmospheric valve V2 is a valve mechanism that allows the variable pressure chamber R2 to communicate with and cut off from the vent hole 19a (atmosphere) in accordance with the advancement and retreat of the plunger 422 relative to the valve body 41. In other words, the atmospheric valve V2 communicates and blocks between the variable pressure chamber R2 and the vent hole 19a in accordance with the relative positions of the valve body 41 and the shaft member 421 (input member 42). The atmospheric valve V2 is a valve that opens or closes the variable pressure chamber R2 with respect to the atmosphere. In other words, the atmospheric valve V2 is a valve that communicates and blocks between the variable pressure chamber R2 and the atmosphere. The atmospheric valve V2 includes an atmospheric valve portion 61b2 and an atmospheric valve seat 422d. The atmospheric valve portion 61b2 is a part of the valve body 61 and is formed on the inner peripheral side of the front end portion of the movable portion 61b. In other words, the inner peripheral side of the front end portion of the movable portion 61b constitutes the atmospheric valve portion 61b2. The atmospheric valve portion 61b2 is formed in an annular shape so as to come into contact with the entire circumference in the circumferential direction of the rear end surface (atmospheric valve seat 422d) of the plunger 422 at the initial position. The atmospheric valve seat 422d is formed in an annular shape at the rear end of the plunger 422. In other words, the rear end portion (flange portion) of the plunger 422 constitutes the atmospheric valve seat 422d. The state where the atmospheric valve portion 61b2 is in contact (seat) with the atmospheric valve seat 422d means that the atmospheric valve V2 is closed, and the state where the atmospheric valve portion 61b2 is separated (separated) from the atmospheric valve seat 422d is the opening of the atmospheric valve V2. Means (open).

(Movable partition plate)
Here, the plate 31 of the movable partition 3 will be described in detail. As shown in FIG. 3, the plate 31 includes a front end surface 311 that is a front end surface, a rear end surface 312 that is a rear end surface, a radiation center portion 313, a plurality of protrusions 314, and a plurality of annular ribs. 315. In other words, the plate 31 includes a plate-like portion 31 a having a front end surface 311 and a rear end surface 312, a radiation center portion 313, a plurality of protrusions 314, and a plurality of annular ribs 315.

The plate-like portion 31a is a curved portion that swells rearward (a cross-sectional convex arc shape) and an annular (annular) portion. The front end surface 311 and the rear end surface 312 are annular surfaces. In addition, the front end surface 311 and the rear end surface 312 can be said to be target portions (surfaces) for forming the protruding portions 314. The radiation center portion 313 is an annular thick portion (for example, a portion protruding forward) formed in the center portion of the front end surface 311. The radiation center portion 313 is formed along the inner peripheral portion 31 b of the plate 31.

The protruding portion 314 is a so-called rib that protrudes forward from the front end surface 311. The protruding portion 314 extends radially from the radial center portion 313 on the front end surface 311 directly or via the assembly portion T. When viewed from the front, the protruding portion 314 has a curved portion 314a extending in a direction intersecting with the radial direction and the circumferential direction of the front end surface 311 at least at the end portion on the radially outer side of the front end surface 311. Yes. In 1st embodiment, the protrusion part 314 whole is comprised by the curved site | part 314a. That is, the projecting portion 314 is configured by a curved portion 314a from a proximal end positioned radially inward to a distal end positioned radially outward (here, the outer peripheral edge of the front end surface 311).

All the protrusions 314 are formed in a convex arc shape on one side in the circumferential direction. In the first embodiment, all the protrusions 314 are formed in the same shape. All the protruding portions 314 are formed at equal intervals in the circumferential direction of the radiation center portion 313, respectively. In the first embodiment, the tips of all the protrusions 314 are located on the outer peripheral edge of the front end surface 311, and are arranged at equal intervals in the circumferential direction of the front end surface 311 on the outer peripheral edge. The base ends (radial inner ends) of all the protruding portions 314 are arranged at equal intervals in the circumferential direction of the radiation center portion 313. In addition, when the base end of the protrusion part 314 here is connected to the assembly part T, the base of the virtual extension line extended from the assembly part T to the radiation | emission center part 313 is the same shape as the other protrusion part 314. It can be said to mean the end. Moreover, when the radiation center part 313 and the assembly | attachment part T are connected, the area | region containing the assembly part T can also be called the radiation center part 313. FIG.

The protruding portion 314 is formed so that the protruding height (width in the axial direction) decreases toward the radially outer side. Further, each protrusion 314 is formed so as not to intersect with the other protrusion 314.
The annular ribs 315 are concentric ribs, and three are provided in the plate-like portion 31a. The annular ribs 315 are formed in concentric circles having different diameters around the center of the front end surface 311.

In the first embodiment, the resin plate 31 is used from the viewpoint of weight reduction or the like, but from the viewpoint of rigidity, a resin containing a fiber material is used as the material of the plate 31. That is, the plate 31 is a fiber-containing resin member. More specifically, the plate 31 is formed of a resin containing carbon fibers. The carbon fiber may be contained in the resin in an amount of, for example, about 10% to 60%. In the embodiment, 20% to 50% is used. The fiber material mixed with the resin may be glass fiber or the like. When the plate 31 is manufactured by, for example, injection molding using a resin containing a fiber material, the direction of fiber orientation (longitudinal direction of the fiber) is along the extending direction of the protruding portion 314. In other words, according to injection molding, the fibers in the resin are oriented in the extending direction of the protrusions 314. For example, when the position corresponding to the radiation center portion 313 is an injection gate, the resin advances radially from the injection gate along the mold of the protruding portion 314. Thereby, the orientation of the fibers is along the flow direction of the resin and along the extending direction of the protrusions 314.

As described above, the manufacturing method of the target member (here, the plate 31) including the protruding portion according to the present embodiment can form the radiation center portion 313 and the plurality of protruding portions 314 on the front end surface 311 of the plate-like portion 31a. An injection molding process for molding a target member by injection molding in which a resin containing a fiber material is injected from the radiation center portion 313 side into the mold is included.

According to the first embodiment, since the protruding portion 314 has the curved portion 314a that extends in a curved shape from the radiation center portion 313 toward the outer peripheral edge of the front end surface 311, the extending portion of the protruding portion 314 extends in the curved portion 314a. The direction intersects the radial direction and the circumferential direction of the plate 31. This makes it possible to adjust the direction of reinforcement of the plate 31 at the site where the curved site 314a is provided. In general radial ribs, since each rib is formed along the radial direction, it is difficult to increase rigidity with respect to a force in a direction intersecting the radial direction of the plate with only the radial ribs. In particular, the edge of the resin plate 31 (end on the outer side in the radial direction) is susceptible to stress in the direction crossing the radial direction, and other reinforcing parts are required, and there is room for improvement in terms of weight reduction and the number of parts. was there. According to the first embodiment, the curved portion 314a allows the extending direction of the protruding portion 314 to intersect the radial direction and the circumferential direction, and the rigidity can be strengthened against the force in the direction intersecting the radial direction. In other words, the directionality of reinforcement or rigidity can be adjusted.

In particular, a plate-like member having a rib such as the plate 31 is often manufactured by injection molding using a resin containing a fiber material. In this case, in the first embodiment, the fiber orientation intersects the radial direction. Therefore, the rigidity in the direction crossing the radial direction can be improved. In addition, the orientation of the fiber in the annular rib 315 tends to be the axial direction (front-rear direction).

Moreover, since the whole protrusion part 314 is comprised by the curvilinear part 314a, the directivity of reinforcement | strengthening of the radial direction of the plate 31 can be adjusted entirely. Furthermore, in the first embodiment, since all the projecting portions 314 are configured by the curved portions 314a, it is possible to adjust the direction of overall strengthening of the plate 31. That is, the rigidity in the direction intersecting the radial direction and the circumferential direction of the plate 31 can be enhanced. In addition, the front-back direction in this embodiment can also be said to be the axial direction of the main body 4 (power piston 40), the axial direction of the hollow cylindrical housing 2, or the moving direction of the movable partition 3. The configuration of the first embodiment can be formed on at least one of the front end surface 311 and the rear end surface 312 in the plate 31. Moreover, in the figure, the reference numerals of the protruding portions 314 are given to only some of the plurality, and the others are omitted. The same applies to other embodiments described below.

<Second embodiment>
The negative pressure booster of the second embodiment is different from the first embodiment in the configuration of the protruding portion. Therefore, a different part is demonstrated. In the description of the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted. In the description of the second embodiment, reference can be made to the drawings and descriptions of the first embodiment.

As shown in FIG. 4, the plate 31 Z of the second embodiment includes a plate-shaped portion 31 a, a radiation center portion 313, a plurality of protrusions 314 Z, and a plurality of annular ribs 315. The protruding portion 314 Z is a so-called rib that protrudes forward from the front end surface 311. The protrusion 314 Z extends radially with respect to the radial center portion 313 on the front end surface 311. The protrusion 314Z has a linear portion 314b extending in a direction intersecting with the radial direction of the radiation center portion 313 when viewed from the front. In 2nd embodiment, the protrusion part 314Z whole is comprised by the linear site | part 314b. That is, the protruding portion 314Z is formed in a linear shape that intersects the radial direction and the circumferential direction from the proximal end on the radially inner side to the distal end on the radially outer side. The protrusion 314Z is inclined with respect to the radial direction of the plate 31 when viewed from the front.

As in the first embodiment, the plurality of protrusions 314Z are formed in the same shape. The plurality of projecting portions 314 Z are formed at equal intervals in the circumferential direction of the radiation center portion 313. The tips of the plurality of protrusions 314Z are located at the circular edge of the front end surface 311 and are arranged at equal intervals in the circumferential direction of the front end surface 311. Base ends (end portions on the inner side in the radial direction) of the plurality of projecting portions 314 Z are arranged at equal intervals in the circumferential direction of the radiation center portion 313. Further, the protrusions 314 do not intersect each other. The effect similar to 1st embodiment is exhibited also by the structure of 2nd embodiment.

<Third embodiment>
The negative pressure type booster of the third embodiment differs from the first embodiment in the configuration of the protrusions. Therefore, a different part is demonstrated. In the description of the third embodiment, the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted. In the description of the third embodiment, reference can be made to the drawings and descriptions of the previous embodiments.

As shown in FIG. 5, the plate 31 Y of the third embodiment includes a plate-like portion 31 a, a radial center portion 313 of the front end surface 311, a plurality of protrusions 314, a plurality of annular ribs 315, and a rear end surface 312. The formed radiation center portion 313 Y, a plurality of protrusions 314 formed on the rear end surface 312, and a plurality of annular ribs (not shown) formed on the rear end surface 312 are provided.

The front end surface 311 side of the plate 31Y has the same configuration as that of the first embodiment. That is, the protrusion 314 is configured by a curved portion 314a that bends in a convex arc shape on one side in the circumferential direction when viewed from the front. The rear end surface 312 side of the plate 31Y has the same configuration as that of the front end surface 311 side when viewed from the rear. Specifically, the protrusion 314Y includes a curved portion 314ay that bends in a convex arc shape on one side in the circumferential direction when viewed from the rear. In other words, the protrusion 314Y is configured by a curved portion 314ay that bends in a convex arc shape on the other side in the circumferential direction when viewed from the front. The protrusion 314Y viewed from the rear is formed in the same shape as the protrusion 314 viewed from the front. In the third embodiment, the base end of the protrusion 314Y is disposed at a position that matches the base end of the protrusion 314 in the axial direction. The plate Y of the third embodiment is formed so that the protruding portion 314 and the protruding portion 314Y intersect when viewed from the axial direction (when seen from the axial direction). In other words, the protrusion 314Y is formed so as to intersect with the protrusion 314 when viewed from the front or the back except for the plate-like portion 31a. FIG. 6 is a perspective view of the plate 31Y.

According to the third embodiment, the same effect as the first embodiment is exhibited. In addition, by forming the protruding portion 314Y on the rear end surface 312, adjustment of the direction of reinforcement and further reinforcement can be achieved. When ribs are formed on the rear end surface 312, only the

bead portions

32 a and 32 b of the diaphragm 32 may be formed on the outer peripheral edge and the inner peripheral edge of the plate 31. Further, the protruding height (axial width) is formed so that the protruding

portions

314 and 314Y become smaller toward the outer side in the radial direction.

Moreover, at least one of the protrusion part 314 and protrusion part 314Y may be comprised by the linear site | part 314b like 2nd embodiment. At this time, similarly to the above, the projecting portion 314 and the projecting portion 314Y may be formed so as to intersect when viewed from the axial direction (see perspectively from the axial direction).
Further, the protrusions 314 Y may be formed so as to be positioned between the adjacent protrusions 314 when viewed from the axial direction (perspectively seen from the axial direction). In other words, the protruding portion 314 and the protruding portion 314Y may be formed so as not to overlap each other when viewed from the axial direction (as viewed in perspective from the axial direction). For example, in FIG. 3, protrusions 314 Y having the same shape as the protrusions 314 (the same shape when viewed from the front) may be disposed between the protrusions 314 on the other end surface 312.

<Fourth embodiment>
The negative pressure type booster of the fourth embodiment differs from the first embodiment in the configuration of the protrusions. Therefore, a different part is demonstrated. In the description of the fourth embodiment, the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted. In the description of the fourth embodiment, reference can be made to the drawings and descriptions of the previous embodiments.

As shown in FIG. 7, the protruding portion 314 X of the plate 31 X according to the fourth embodiment has a proximal end side portion 314 X 1 with one end connected to the radiation center portion 313, and the front end surface 311 from the other end of the proximal end side portion 314 X 1. It is comprised by the front end side site | part 314X2 extended toward radial direction outer side. The proximal portion 314X1 can also be referred to as a radially inner portion, and the distal end portion 314X2 can also be referred to as a radially outer portion. The proximal end portion 314X1 extends along the radial direction of the front end surface 311. The proximal end side portion 314X1 of the fourth embodiment is a portion from the radiation center portion 313 to the annular rib 315 formed on the outermost peripheral side in the protruding portion 314X.

The tip side portion 314X2 is configured by a curved portion 314a. The tip side portion 314X2 of the fourth embodiment is a portion from the outermost annular rib 315 to the radially outer edge of the front end surface 311. According to the fourth embodiment, the same effect as that of the first embodiment is exerted on the outer peripheral edge that is susceptible to stress.

Note that the tip portion 314X2 may be a linear portion 314b. Further, the radially outer end of the proximal end portion 314X1 (the radially inner end of the distal end portion 314X2) may be an annular rib 315 other than the outermost annular rib 315, or a position other than the annular rib 315. It may be. However, since the boundary between the base end side portion 314X1 and the tip end side portion 314X2 is the annular rib 315, the positional deviation between the protruding portions is suppressed, the rigidity of each portion is easily made constant, and the manufacturing accuracy is improved. be able to. Also, in the fourth embodiment, as in the third embodiment, the other-side radiation center portion and the other-side protruding portion may be provided.

<Fifth embodiment>
The negative pressure type booster of the fifth embodiment is different from the first embodiment in the configuration of the protruding portion. Therefore, a different part is demonstrated. In the description of the fifth embodiment, the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted. In the description of the fifth embodiment, reference can be made to the drawings and descriptions of the previous embodiments.

As shown in FIG. 8, the plurality of protrusions 314 W 1 and 314 W 2 according to the fifth embodiment are curved first protrusions 314 W 1 that bend in a convex arc shape on one side in the circumferential direction of the front end surface 311 and the circumferential direction of the front end surface 311. The curved second protrusion 314W2 that bends in a convex arc shape on the other side. The first protrusion 314W1 is formed to intersect the second protrusion 314W2. According to the fifth embodiment, the same effect as that of the first embodiment is exhibited.

Further, in the fifth embodiment, the protrusion height in the axial direction is formed so that the second protrusion 314W2 is higher than the first protrusion 314W1. Thereby, in the injection molding, the resistance at the intersecting point is lowered, and the molding accuracy is improved.

<Sixth embodiment>
The negative pressure type booster of the sixth embodiment differs from the first embodiment in the configuration of the radiation center portion and the protruding portion. Therefore, a different part is demonstrated. In the description of the sixth embodiment, the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted. In the description of the sixth embodiment, reference can be made to the drawings and descriptions of the previous embodiments.

As shown in FIG. 9, the plate 31 V of the sixth embodiment includes a plate-shaped portion 31 a, a plurality of radiation center portions 313 V, a plurality of protrusions 314 V, and a plurality of radial ribs 316. Four radiation center portions 313 V are formed on the front end surface 311. Each radiation center portion 313V is formed at a predetermined position in the radial direction of the front end surface 311 (here, a position that is not both end portions), and is formed at equal intervals in the circumferential direction (here, at intervals of 90 °). The plurality of protrusions 314V extend radially from the respective radiation center portions 313V. Of the plurality of protrusions 314V, the protrusion 314Va that reaches the outer edge in the radial direction of the front end surface 311 is configured by a curved portion 314a.

The radial rib 316 is a rib extending in the radial direction from the center of the front end surface 311. The radial ribs 316 are arranged at equal intervals in the circumferential direction of the front end surface 311 (only a part of the plurality of symbols is given a symbol in the drawing). It can be said that the radiation center portion 313 V is formed on the radial rib 316. According to the sixth embodiment, the same effect as the first embodiment is exhibited. Further, by forming the plurality of radiation center portions 313V, it is possible to adjust the direction of further strengthening. Note that the protrusion 314Va may be configured by a linear portion 314b.

<Seventh embodiment>
The negative pressure type booster of the seventh embodiment differs from the first embodiment in that the radial center portion and the protruding portion are provided on the rear shell. Therefore, a different part is demonstrated. In the description of the seventh embodiment, the same components as those in the first embodiment are denoted by the same reference numerals and the description thereof is omitted. In the description of the seventh embodiment, reference can be made to the drawings and descriptions of the previous embodiments.

As shown in FIG. 10, the annular bottom surface portion 221 of the rear shell 22 of the seventh embodiment includes an annular rear end surface 221b, a radial protrusion 223 formed at the center portion of the rear end surface 221b, and a rear side from the front end surface 221b. A plurality of projecting portions 224 projecting from each other. The radiation center portion 223 has the same configuration as the radiation center portion 313 of the first embodiment, and is formed in an annular shape at the center portion of the front end surface 221b. The protruding portion 224 has the same configuration as the protruding portion 314 of the first embodiment, and is a curved portion 224a that extends radially from the radial center portion 223 and extends in a direction intersecting the radial direction and the circumferential direction of the rear end surface 221b. It is configured. The annular bottom surface portion 221 is formed in a convex arc shape in cross section with the center slightly bulging backward. The protruding portion 224 is formed such that the protruding height decreases toward the outer side in the radial direction. The effect similar to 1st embodiment is exhibited also by 7th embodiment.

In addition, the said structure may be provided in the front end surface and / or back end surface of the cyclic | annular bottom face part 211 of the front shell 21. FIG. In addition, the above configuration may be provided on the front end surface of the annular bottom surface portion 221 of the rear shell 22. Further, the shape of the protrusion may be the same as in the second to sixth embodiments.

(Other)
The present invention is not limited to the above embodiment. The curved portion 314a may have a constant curvature or may change in the middle. The target member may be molded by press molding or the like. The target member is mainly manufactured from a resin containing a fiber material, but may be, for example, a plastic that does not contain a fiber material. In the above embodiment, all the protrusions extending from the radial center portion 313 to the radially outer end portion of the front end surface 311 are only the curved portion 314a, the straight portion 314b, or the proximal portion and the distal portion. It is formed by a combination. However, the present invention is not limited to this, and it is only necessary that at least one projecting portion is constituted by a curved portion 314a or a straight portion 314b at least at the radially outer end of the front end surface 311. In addition, the embodiments can be combined with each other. Further, the protruding height of the protruding portion may be constant.

Further, the plurality of protrusions (for example, the protrusions 314) in the above embodiment may not be arranged at equal intervals in the circumferential direction, and may be formed at arbitrary intervals. Further, the radially outer end portion of the front end surface 311 is a portion having a width in the radial direction. For example, from the outer edge of the front end surface 311 (or the rear end surface) that is a rib formation target region, It can be defined as a region (region) up to a position that enters the inside in the radial direction by a length corresponding to a predetermined proportion of the outer diameter (outer edge radius) of the end surface 311. For example, the predetermined ratio may be set to 1/3 or less (for example, 1/4, 1/5,..., 1/10, etc.) (0 <predetermined ratio ≦ 1/3). In this case, for example, the plurality of projecting portions 314 are at least from the edge on the outer peripheral side of the front end surface 311 to a position that enters the inside in the radial direction by a length of 1/3 of the outer diameter (radius) of the front end surface 311. It can be said that the part has a curved part 314a and / or a straight part 314b.

In addition, the manufacturing method of the present embodiment includes a housing having one shell constituting one portion in the axial direction and the other shell disposed on the other axial side of the one shell, and the shaft inside the housing. A movable partition wall that is divided into a negative pressure chamber on one side of the direction and a variable pressure chamber on the other side of the axial direction and movable in the axial direction, and a main body portion that communicates and blocks between the variable pressure chamber and the atmosphere. A method of manufacturing a target member of a negative pressure type booster comprising a fiber material for a mold capable of forming a radial center portion and a plurality of protrusions on one axial end surface of the target member. An injection molding step of molding the target member by injection molding injecting the resin from the radial center side, wherein the target member is the one shell, the other shell, or the movable partition wall, and from the axial direction Smell when seen The plurality of projecting portions extend radially from the radiation center portion, and at least one of the plurality of projecting portions is at least a radial direction of the one end surface at an end portion on a radially outer side of the one end surface, and It has a curved portion or a straight portion extending in a direction intersecting the circumferential direction.

Claims

A housing having one shell constituting one portion in the axial direction and the other shell disposed on the other axial side of the one shell;
A movable partition wall that partitions the inside of the housing into a negative pressure chamber on one side in the axial direction and a variable pressure chamber on the other side in the axial direction and is movable in the axial direction;
A main body for communicating / blocking between the variable pressure chamber and the atmosphere;
A negative pressure booster comprising:
At least one of the one shell, the other shell, and the movable partition wall protrudes in the axial direction from a radial center portion formed on an annular one end surface that is one end surface in the axial direction, and the one end surface A plurality of protrusions,
When viewed from the axial direction,
The plurality of protrusions extend radially from the radiation center portion,
At least one of the plurality of protrusions has a curved portion or a linear portion extending in a direction intersecting the radial direction and the circumferential direction of the one end surface at least at an end portion on the radially outer side of the one end surface. Negative pressure booster.
The negative pressure type booster according to claim 1, wherein the protruding portion is configured by the curved portion or the linear portion.
The projecting portion is composed of a base end side portion whose one end is connected to the radiation center portion, and a tip end side portion extending from the other end of the base end side portion toward the radially outer side of the one end face,
The base end side portion extends along a radial direction of the one end face,
The negative pressure booster according to claim 1, wherein the tip side portion is configured by the linear portion or the curved portion.
The other end surface facing away from the one end surface is formed with the other side radiation center portion and a plurality of other side protrusion portions protruding in the axial direction,
When viewed from the axial direction,
The plurality of other side protrusions extend radially from the other side radiation center,
At least one of the plurality of other-side protruding portions is a curved portion or a linear portion extending in a direction intersecting with the radial direction and the circumferential direction of the other end surface at least at the radially outer end of the other end surface. The negative pressure booster according to any one of claims 1 to 3, wherein
5. The negative pressure type multiple according to claim 4, wherein the protruding portion and the other-side protruding portion are configured by the curved portion or the linear portion, and are formed so as to intersect each other when viewed from the axial direction. Force device.
The protruding portion and the other-side protruding portion are configured by the curved portion or the linear portion, and are formed so that the other-side portion is located between the adjacent protruding portions when viewed from the axial direction. The negative pressure type booster as claimed in claim 4.