JP6635060B2 - Negative pressure booster - Google Patents

Description

  The present invention relates to a vacuum booster.

  2. Description of the Related Art Conventionally, for example, a negative pressure booster disclosed in Patent Document 1 below is known. The conventional negative pressure booster includes tie rod bolts that penetrate the front shell and the rear shell and are arranged at two positions in the diameter direction of the front shell and the rear shell. The tie rod bolt is formed with an enlarged front flange and a rear flange, and the front flange hermetically contacts the inside of the front seat surface of the front shell via a seal made of a retainer and an elastic member. ing.

JP 2012-232638 A

  In the above-described conventional negative pressure booster, in order to ensure airtightness of a constant pressure chamber (negative pressure chamber) formed in a housing (booster shell) including a front shell and a rear shell, a front shell and a front flange are formed. It is necessary to interpose two members, a retainer and a seal, between them. In this case, the number of components constituting the negative pressure type booster increases and the structure becomes complicated, so that the assembling workability of assembling the retainer and the seal to the tie rod bolt deteriorates.

  The present invention has been made to solve the above problems. That is, an object of the present invention is to provide a negative pressure booster that can simplify the structure and improve the assembling workability.

In order to solve the above-mentioned problems, an invention of a negative pressure booster according to claim 1 includes a hollow booster shell, a movable partition that hermetically partitions the booster shell into a negative pressure chamber and a transformer chamber, and a booster. A tie rod bolt that hermetically penetrates the shell and the movable partition, fixes the booster shell to the vehicle body at one end, and supports a master cylinder at the other end. The tie rod bolt has an enlarged portion that is enlarged so as to face the inner surface of the booster shell, and is interposed between the inner surface of the booster shell and the enlarged portion of the tie rod bolt, and An annular plastic deformation portion that is plastically deformed by being sandwiched between the inner surface and the enlarged portion of the tie rod bolt has an annular plastic deformation portion that is in close contact with the inner surface of the booster shell and the enlarged portion of the tie rod bolt. Comprising a pole tip, the seal portion has a support portion of the annular supporting the plastic deformation portion, toward at least the enlarged diameter portion of the tie rod bolts of the enlarged diameter portion of the inner surface and the tie rod bolts booster shell projecting As such, the support portion supports the plastic deformation portion, and the plastic deformation portion protruding toward the enlarged portion of the tie rod bolt is such that the distal end side facing the enlarged portion of the tie rod bolt is flat in the circumferential direction. It has a formed flat portion, and has a slope portion connected to the flat portion so that the cross-sectional shape of the cross section in the virtual plane including the axis is a trapezoid with the top side being the upper base, and the inner diameter of the flat portion Is set to be larger than the outer diameter of the enlarged portion of the tie rod bolt, and the inner diameter of the slope connected to the inner peripheral end of the flat portion is flat from the inner peripheral end of the flat portion toward the support portion. From the inside diameter of the part Is provided so as to be reduced in diameter.

  According to this, the plastically deformed portion of the seal portion can be plastically deformed when the master cylinder is fastened to the tie rod bolt, for example, by fastening the nut, and hermetically seal the gap between the inner surface and the enlarged diameter portion. it can. Thereby, the structure can be simplified as compared with the above-described conventional negative pressure type booster which uses the elastic member and the retainer to hermetically seal, and as a result, the assembling workability is improved. can do.

It is a schematic diagram showing the composition of the brake equipment provided with the vacuum booster concerning an embodiment of the present invention. FIG. 2 is an overall view illustrating a configuration of a negative pressure booster of FIG. 1. FIG. 3 is a cross-sectional view illustrating a seal portion of FIG. 2. FIG. 4 is a cross-sectional view illustrating an assembled state of the seal unit in FIG. 3. It is sectional drawing which shows the seal part which concerns on the 1st modification of embodiment of this invention. FIG. 6 is a cross-sectional view illustrating an assembled state of the seal unit of FIG. 5. It is sectional drawing which shows the seal part which concerns on the 2nd modification of embodiment of this invention. It is sectional drawing which shows the seal part which concerns on the 3rd modification of embodiment of this invention. It is sectional drawing which shows the seal part which concerns on the 4th modification of embodiment of this invention. FIG. 10 is a cross-sectional view illustrating an assembled state of the seal unit in FIG. 9. It is sectional drawing which shows the other modification of embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments and modifications, the same or equivalent parts are denoted by the same reference numerals in the drawings. Each drawing used in the description is a conceptual diagram, and the shape of each part may not always be strict.

  As shown in FIG. 1, a negative pressure booster 100 according to the present embodiment constitutes a brake device 1 of a vehicle. The vehicle brake device 1 includes a cylinder mechanism 2. The cylinder mechanism 2 includes a master cylinder 21, master pistons 22 and 23, and a master reservoir 24. Master pistons 22 and 23 are slidably disposed in master cylinder 21. The master pistons 22, 23 partition the inside of the master cylinder 21 into a first master chamber 21a and a second master chamber 21b. The master reservoir 24 is a reservoir tank having a pipe communicating with the first master chamber 21a and the second master chamber 21b. The master reservoir 24 and each of the master chambers 21a and 21b are connected or disconnected by the movement of the master pistons 22 and 23.

  The cylinder mechanism 2 includes a wheel cylinder 25, a wheel cylinder 26, a wheel cylinder 27, and a wheel cylinder 28. The wheel cylinder 25 is arranged on the left rear wheel RL of the vehicle. The wheel cylinder 26 is disposed on the right rear wheel RR of the vehicle. The wheel cylinder 27 is arranged on the left front wheel FL of the vehicle. The wheel cylinder 28 is arranged on the right front wheel FR of the vehicle. The master cylinder 21 and each of the wheel cylinders 25 to 28 are connected via the actuator 3. Thereby, each of the wheel cylinders 25 to 28 applies a braking force to the left rear wheel RL, the right rear wheel RR, the left front wheel FL, and the right front wheel FR. Although not described in detail, the actuator 3 includes a pipe, an electric pump, a solenoid valve, a check valve, and the like (not shown).

  In the brake device 1 of the vehicle, when the driver depresses the brake pedal 29, the pedaling force is boosted by the negative pressure type booster 100 airtightly connected to the master cylinder 21. 23 is pressed. As a result, the same master cylinder pressure is generated in the first master chamber 21a and the second master chamber 21b. The master cylinder pressure is transmitted to wheel cylinders 25 to 28 via actuator 3.

  As shown in FIG. 2, the negative pressure booster 100 includes a hollow booster shell 110, and the movable partition 120 and the piston 130 are assembled to the booster shell 110 so as to be integrally movable in the front-rear direction. ing. The inside of the booster shell 110 is partitioned by the movable partition 120 into a negative pressure chamber R1 at the front and a variable pressure chamber R2 at the rear.

  The booster shell 110 includes a front shell 111 and a rear shell 112 formed of, for example, iron, aluminum, or resin (reinforced plastic). The front shell 111 is provided with a negative pressure inlet 111a for connecting the negative pressure chamber R1 to a negative pressure source (for example, an intake manifold of an engine (not shown)). A check valve 113 is provided at the negative pressure introduction port 111a. The check valve 113 is configured to permit communication of air from the negative pressure chamber R1 side to the negative pressure source side and to cut off communication of air from the negative pressure source side to the negative pressure chamber R1 side. Further, the booster shell 110 has tie rod bolts 114 that penetrate the front shell 111 and the rear shell 112 airtightly at two locations in the radial direction. In FIG. 2, only one tie rod bolt 114 is shown. Further, the booster shell 110 has a rear bolt 115 that penetrates the rear shell 112 in an airtight manner.

  The tie rod bolt 114 is, for example, a bolt manufactured by forging using a forging die, and the front shell 111 side (the front side of the booster shell 110 and the other end side) is connected to the master cylinder via the flange 116. The nut 21 is fastened to the nut 21 by a nut 117. Thus, the two tie rod bolts 114 support the master cylinder 21 on the front shell 111 side (the other end side). As shown in FIGS. 2 and 3, the tie rod bolt 114 has an annular enlarged portion 114 a radially outwardly enlarged so as to face the inner surface 111 b of the front shell 111 (booster shell 110). are doing. Further, the tie rod bolt 114 on the rear shell 112 side (on the rear side and one end side of the booster shell 110) and the rear bolt 115 are fixed to a stationary member, for example, a vehicle body (not shown) of the vehicle. The rear bolt 115 is also a bolt manufactured by forging using a forging die.

  Further, the booster shell 110 has a retainer 118 disposed between the inner surface 111b of the front shell 111 and the enlarged diameter portion 114a of the tie rod bolt 114. The retainer 118 is formed in an annular shape from a metal material (for example, aluminum material) having a lower rigidity than the front shell 111 and the tie rod bolt 114, and has a through hole 118a through which the tie rod bolt 114 is inserted as shown in FIG. Have.

  In the present embodiment, the seal portion 119 is provided integrally with the retainer 118. That is, in the present embodiment, the support portion of the seal portion 119 becomes the retainer 118. The seal portion 119 is formed to be annular, and is interposed between the inner surface 111b of the booster shell 110 (more specifically, the front shell 111) and the enlarged diameter portion 114a of the tie rod bolt 114. . The seal portion 119 is configured to include an annular first annular protrusion 119a and an annular second annular protrusion 119b as an annular plastic deformation portion supported by a retainer 118 as a support portion. Then, as described later, when the master cylinder 21 is fastened to the booster shell 110 by the nut 117, the seal portion 119 connects the first annular protrusion 119a and the second annular protrusion 119b to the booster shell 110 (the front shell 111). ) Is plastically deformed by being pinched between the inner surface 111b of the tie rod and the enlarged diameter portion 114a of the tie rod bolt 114. Thus, the seal portion 119 is airtight because the first annular protrusion 119a and the second annular protrusion 119b are in close contact with the inner surface 111b of the booster shell 110 (the front shell 111) and the enlarged diameter portion 114a of the tie rod bolt 114. Exhibits a sealing function.

  The first annular projection 119a projects toward the front shell 111 in a state where the tie rod bolt 114 is inserted through the through hole 118a of the retainer 118 (interposed state). The second annular projection 119b projects toward the enlarged diameter portion 114a of the tie rod bolt 114 in a state where the tie rod bolt 114 is inserted through the through hole 118a of the retainer 118 (interposed state).

  As shown in FIG. 3, the first annular protrusion 119 a and the second annular protrusion 119 b are formed such that the cross-sectional shape in a virtual plane including the axis of the retainer 118 becomes trapezoidal. Specifically, the first annular protrusion 119a and the second annular protrusion 119b have an inner diameter larger than the outer diameter of the enlarged diameter portion 114a of the tie rod bolt 114, and are formed flat in the circumferential direction of the retainer 118. It has a flat portion 119a1 and a flat portion 119b1. Here, the flat portion 119a1 and the flat portion 119b1 have a trapezoidal upper base in the cross-sectional shape of the virtual plane. The flat portion 119a1 is provided on the front end side facing the inner surface 111b of the front shell 111. The flat portion 119b1 is provided on the distal end side of the tie rod bolt 114 facing the enlarged diameter portion 114a. Further, the first annular projection 119a and the second annular projection 119b are connected to the inner peripheral ends of the flat portions 119a1 and 119b1, and are directed from the inner peripheral ends of the flat portions 119a1 and 119b1 to the retainer 118. In addition, there are a slope portion 119a2 and a slope portion 119b2 whose inner diameter is smaller than the outer diameter of the enlarged diameter portion 114a along the axial direction of the retainer 118.

  The movable partition wall 120 is provided so as to be movable in the front-back direction along the axis of the piston 130 in the booster shell 110. The movable partition 120 includes a diaphragm 121 formed of an annular elastic member (for example, an annular rubber material). The diaphragm 121 includes an outer bead portion 121a, an inner bead portion 121b, and an annular seat portion 121c connecting the outer bead portion 121a and the inner bead portion 121b. The outer peripheral bead portion 121a is disposed at a connection portion between the front shell 111 and the rear shell 112, and is hermetically sandwiched between the front shell 111 and the rear shell 112. The inner peripheral bead portion 121b is air-tightly fixed to the outer peripheral portion of the piston 130.

  The piston 130 is connected to the movable partition 120, that is, the inner periphery of the diaphragm 121. The piston 130 has a main body 131 made of resin and formed in a cylindrical shape. The main body 131 is hermetically attached to the rear shell 112 of the booster shell 110 at the center so as to be movable in the front-rear direction along the axial direction. Further, the main body 131 is urged rearward by a return spring S1 interposed between the main body 131 and the front shell 111 of the booster shell 110. A portion of the main body 131 (that is, the piston 130) protruding outside the booster shell 110 is covered and protected by the boot B.

  A pair of (only one is shown in FIG. 2) negative pressure communication passages 132 are provided inside the main body 131. The negative pressure communication passage 132 has a front end communicating with the negative pressure chamber R1 of the booster shell 110 and a rear end communicating with the inside of the main body 131. Further, inside the main body 131, the input shaft 141 and the plunger 142 are assembled so as to be coaxial, and the valve mechanism 150 and the filter 143 are assembled so as to be coaxial. Further, a reaction member 144 made of an elastic member (for example, a rubber material) and an output shaft 145 are assembled coaxially inside the main body 131 in front of the plunger 142.

  The input shaft 141 is movable in the front-rear direction along the direction of the axis of the main body 131, and is articulated to the connecting portion of the plunger 142 at a spherical tip. The input shaft 141 is connected to a brake pedal 29 via a yoke (not shown) by a screw portion provided at a rear end, and is configured to receive a pedaling force acting on the brake pedal 29 as an input and to move forward. . The input shaft 141 is engaged with the return spring S2 via the ring member 146, and is urged rearward by the return spring S2.

  The plunger 142 abuts on the center of the rear surface of the reaction member 144 at the tip. Further, the plunger 142 engages with the key member in an annular groove formed in the central portion. Further, the plunger 142 is provided at its rear end with an annular atmospheric valve seat in the valve mechanism 150. The key member has a function of restricting the plunger 142 from moving in the front-rear direction with respect to the main body 131 of the piston 130 and a limit position for the piston 130 to move rearward with respect to the booster shell 110 (a rearward return position of the piston 130). This is a member having a defining function.

  The reaction member 144 is housed in the rear cylindrical portion 145a of the output shaft 145, and is assembled to the main body 131 of the piston 130 together with the rear cylindrical portion 145a of the output shaft 145. The reaction member 144 is configured such that a central portion of the rear surface swells and deforms rearward in a state of being accommodated in the rear cylindrical portion 145a.

  The output shaft 145 pushes the master pistons 22 and 23 of the master cylinder 21 at the distal end. The output shaft 145 transmits a reaction force received from the master pistons 22 and 23 of the master cylinder 21 to the reaction member 144 during the braking operation.

  The valve mechanism 150 includes a negative pressure valve seat formed integrally with the rear end of the negative pressure communication passage 132 in the main body 131 of the piston 130 and an atmospheric valve seat formed integrally with the rear end of the plunger 142. Have. Further, the valve mechanism 150 includes a cylindrical valve body 151 arranged coaxially with the atmosphere valve seat. The valve element 151 has an annular mounting portion and a cylindrical movable portion formed integrally with the mounting portion and movable along the axial direction. The mounting portion of the valve element 151 is hermetically assembled in the main body 131 of the piston 130, and is held by the main body 131 by the annular member 146.

  The movable portion of the valve element 151 is a negative pressure valve portion that constitutes a negative pressure valve that communicates with or shuts off the negative pressure chamber R1 and the variable pressure chamber R2 together with the negative pressure valve seat by being seated or separated from the negative pressure valve seat. Having. In addition, the movable portion of the valve element 151 forms an atmosphere valve portion that constitutes an atmosphere valve that communicates or shuts off between the variable pressure chamber R2 and the atmosphere together with the atmosphere valve seat by being seated or separated from the atmosphere valve seat. Have.

  In the negative pressure booster 100 configured as described above, the tie rod bolt 114 on the rear shell 112 side (the rear side of the booster shell 110) and the rear bolt 115 are attached to the vehicle body side (not shown) by, for example, nut fastening. Fixed. In the negative pressure booster 100, as shown in FIG. 4, the master cylinder 21 is fastened to the front shell 111 side of the tie rod bolt 114 (the front side of the booster shell 110) by a nut 117 via a flange 116. At this time, the front shell 111 is pushed toward the enlarged diameter portion 114 a of the tie rod bolt 114 by the tightening force of the nut 117. As a result, the flat portion 119a1 of the first annular protrusion 119a provided integrally with the retainer 118 is pressed by the inner surface 111b of the front shell 111 as shown in FIG. 4, and the inclined portion 119a2 is directed inward and outward. Due to plastic deformation (buckling deformation), the inner surface 111b of the front shell 111 is tightly adhered to the inner surface 111b. That is, the flat portion 119a1 of the first annular protrusion 119a constituting the seal portion 119 comes into surface contact with the inner surface 111b of the front shell 111, thereby exhibiting sealing properties.

  Further, as shown in FIG. 4, the slope portion 119 b 2 of the second annular protrusion 119 b provided integrally with the retainer 118 is concaved by being pressed against the outer peripheral end of the enlarged diameter portion 114 a of the tie rod bolt 114. Plastically deforms (depresses and deforms) and closely adheres to the outer peripheral surface of the enlarged diameter portion 114a with airtightness. As described above, when the slope portion 119b2 of the second annular protrusion 119b is depressed and deformed, the tie rod bolt 114 and the retainer 118 are firmly fixed and positioned. In addition, the slope 119b2 of the second annular protrusion 119b constituting the seal 119 is depressed and deformed, so that the slope 119b2 of the second annular protrusion 119b exhibits a sealing property in the direction of the axis of the tie rod bolt 114. At the same time, the tie rod bolt 114 also exhibits a sealing property in the radial direction.

  Therefore, the first annular projection 119a and the second annular projection 119b are plastically deformed by assembling the negative pressure booster 100 to the vehicle body of the vehicle and mounting the master cylinder 21 to the negative pressure booster 100. In addition, a sealing property for hermetically sealing a gap between the front shell 111 and the enlarged diameter portion 114a is exhibited. Thereby, the airtightness of the negative pressure chamber R1 formed in the booster shell 110 of the negative pressure type booster 100 is sufficiently ensured.

  In the negative pressure type booster 100, the variable pressure chamber R2 is secured by the valve mechanism 150 in accordance with the movement of the input shaft 141 and the plunger 142 in the front-rear direction with respect to the main body 131 as described above. It can communicate with the negative pressure chamber R1 or the atmosphere. That is, when the input shaft 141 and the plunger 142 move forward from the position shown in FIG. 2 (the original position and the return non-operation position) with respect to the main body 131, the negative pressure valve portion is seated on the negative pressure valve seat, and The valve seat separates from the atmospheric valve. In this case, the communication between the variable pressure chamber R2 and the negative pressure chamber R1 is interrupted, and the variable pressure chamber R2 communicates with the atmosphere. Then, in this case, the atmosphere flows into the transformation chamber R2 through the filter 143, the inside of the valve body 151, a gap with the atmosphere valve seat, a communication passage provided in the main body 131, and the like. As a result, the pressure in the variable pressure chamber R2 becomes larger than the pressure in the negative pressure chamber R1, so that the movable partition 120 and the piston 130 operate forward with the operation of the input shaft 141 forward, and the output shaft 145 Operate forward. As a result, the output shaft 145 presses the master pistons 22 and 23 of the master cylinder 21, and the master cylinder pressure is transmitted to the wheel cylinders 25 to 28 via the actuator 3.

  When the input shaft 141 and the plunger 142 return to the non-return position (original position) with respect to the main body 131, the atmospheric valve seat is seated on the atmospheric valve, and the negative pressure valve is separated from the negative pressure valve seat. I do. In this case, the atmosphere valve is closed to cut off communication between the variable pressure chamber R2 and the atmosphere, and the negative pressure valve is opened to connect the negative pressure chamber R1 and the variable pressure chamber R2. In this case, air is sucked from the variable pressure chamber R2 into the negative pressure chamber R1 through the communication path provided in the main body 131, the gap between the negative pressure valve section and the negative pressure valve seat, the negative pressure communication path 132, and the like. As a result, since the pressure in the variable pressure chamber R2 and the pressure in the negative pressure chamber R1 become substantially equal, the movable partition wall 120 and the piston 130 operate rearward with the rearward operation of the input shaft 141 by the urging force of the return spring S2. Then, the output shaft 145 operates backward. As a result, the pressing of the master pistons 22 and 23 of the master cylinder 21 by the output shaft 145 is released, and the master cylinder pressure decreases.

  As can be understood from the above description, the negative pressure booster 100 of the above embodiment includes a hollow booster shell 110 including a front shell 111 and a rear shell 112, and the booster shell 110 is connected to the negative pressure chamber R1 and the transformation chamber R2. The movable partition wall 120 is airtightly divided into the movable shell 120, the booster shell 110 and the movable partition wall 120, and the booster shell 110 is fixed to the vehicle body at one end side (the rear shell 112 side) and the other end side (front side). And a tie rod bolt 114 that supports the master cylinder 21 on the shell 111 side), so that the tie rod bolt 114 faces the inner surface 111b of the booster shell 110 (the front shell 111). The booster shell 110 (the front shell 1) has an enlarged diameter portion 114a. 1) is interposed between the inner surface 111b of the tie rod bolt 114 and the enlarged portion 114a of the tie rod bolt 114, and is sandwiched between the inner surface 111b of the booster shell 110 (the front shell 111) and the enlarged portion 114a of the tie rod bolt 114 to be plastic. It has a first annular protrusion 119a and a second annular protrusion 119b which are deformable annular plastically deformed portions, and the first annular protrusion 119a and the second annular protrusion 119b are inner surfaces of the booster shell 110 (front shell 111). An annular seal portion 119 is provided in close contact with 111b and the enlarged diameter portion 114a of the tie rod bolt 114.

  In this case, the seal portion 119 serves as an annular support portion for supporting the first annular protrusion 119a and the second annular protrusion 119b, and the inner surface 111b of the booster shell 110 (front shell 111) and the enlarged diameter portion 114a of the tie rod bolt 114. Are provided integrally with an annular retainer 118 interposed therebetween.

  According to these, the seal portion 119 is interposed between the inner surface 111b of the booster shell 110 (front shell 111) and the enlarged diameter portion 114a of the tie rod bolt 114 penetrating the booster shell 110 (front shell 111). As a result, the master cylinder 21 is plastically deformed when the nut 117 is fastened to the tie rod bolt 114 by the nut 117, so that the gap between the inner surface 111b and the enlarged diameter portion 114a can be hermetically sealed. Thereby, the structure can be simplified as compared with the above-described conventional negative pressure type booster which uses the elastic member and the retainer to hermetically seal, and as a result, the assembling workability is improved. can do.

  Further, it can be provided integrally with the retainer 118 as a support member for the seal portion 119. Accordingly, the number of components can be reduced as compared with the above-described conventional vacuum booster in which the elastic member and the retainer are separately and airtightly sealed using two members. Therefore, the assembling work process can be simplified, and as a result, the assembling workability can be improved.

  In this case, in the seal portion 119, the first annular protrusion 119a and the second annular protrusion 119b are at least one of the inner surface 111b of the booster shell 110 (the front shell 111) and the enlarged diameter portion 114a of the tie rod bolt 114. It is supported by the retainer 118 so as to protrude toward the inner surface 111b and the enlarged diameter portion 114a.

  According to this, the first annular protrusion 119a and the second annular protrusion 119b can be securely plastically deformed by fastening the master cylinder 21 to the tie rod bolt 114 with a nut. Therefore, the gap between the inner surface 111b of the booster shell 110 (front shell 111) and the enlarged diameter portion 114a of the tie rod bolt 114, in other words, the internal space of the booster shell 110 (specifically, the negative pressure chamber R1) is airtight. Can be sealed. Thereby, the negative pressure type booster 100 can be favorably operated.

  In this case, the first annular protrusion 119a and the second annular protrusion 119b, which are plastically deformed portions, are formed such that the distal end side facing the inner surface 111b of the booster shell 110 (front shell 111) or the enlarged diameter portion 114a of the tie rod bolt 114 has a circumferential direction. Has a flat portion 119a1 and a flat portion 119b1 formed to be flat.

  According to this, with the nut fastening of the master cylinder 21 to the tie rod bolt 114, the flat portion 119a1 of the first annular projection 119a can be appropriately brought into close contact with the inner surface 111b of the booster shell 110 (front shell 111). At the same time, the flat portion 119b1 of the second annular protrusion 119b can be appropriately brought into close contact with the enlarged diameter portion 114a of the tie rod bolt 114. Therefore, the gap between the inner surface 111b of the booster shell 110 (the front shell 111) and the enlarged diameter portion 114a of the tie rod bolt 114, in other words, the internal space of the booster shell 110 (specifically, the negative pressure chamber R1) is more reliably formed. Can be hermetically sealed. Thereby, the negative pressure type booster 100 can be favorably operated.

  In this case, the first annular protrusion 119a and the second annular protrusion 119b, which are annular protrusions, have flat portions 119a1 and 119a1 such that the cross-sectional shape of the cross-section in the virtual plane including the axis is trapezoidal with the tip side being the upper base. It has a slope portion 119a2 and a slope portion 119b2 connected to the flat portion 119b1.

  According to this, with the fastening of the master cylinder 21 to the tie rod bolt 114 with the nut, in particular, the slope 119a2 of the first annular protrusion 119a can be securely and easily plastically deformed (buckled). Accordingly, the flat portion 119a1 of the first annular protrusion 119a is properly in close contact with the inner surface 111b of the booster shell 110 (the front shell 111), and can exhibit good sealing properties. Therefore, the negative pressure booster 100 can be favorably operated.

  In this case, the second annular projection 119b, which is a plastically deformed portion that projects toward the enlarged diameter portion 114a of the tie rod bolt 114, has an inner diameter of the flat portion 119b1 larger than the outer diameter of the enlarged diameter portion 114a of the tie rod bolt 114. The inner diameter of the slope portion 119b2 connected to the flat portion 119b1 is set to be smaller than the inner diameter of the flat portion 119b1 from the inner peripheral end of the flat portion 119b1 toward the retainer 118 serving as a support portion. The inclined surface 119b2 comes into contact with the enlarged diameter portion 114a of the tie rod bolt 114 and is plastically deformed, and comes into close contact with the enlarged diameter portion 114a of the tie rod bolt 114.

  According to this, the slope portion 119b2 of the second annular protrusion 119b constituting the seal portion 119 abuts on the enlarged diameter portion 114a of the tie rod bolt 114, so that the inclined portion 119b2 is plastically deformed (depressed and deformed) so that the enlarged diameter portion 114a bites. )can do. Accordingly, the second annular projection 119b can firmly position the tie rod bolt 114, and can be in close contact with the enlarged diameter portion 114a in the radial direction and the axial direction, thereby exhibiting good sealing properties. it can. Therefore, the negative pressure booster 100 can be favorably operated.

(First Modification of Embodiment)
In the above embodiment, the first annular protrusion 119a and the second annular protrusion 119b that constitute the seal portion 119 provided integrally with the retainer 118 have an inner diameter larger than the outer diameter of the enlarged diameter portion 114a of the tie rod bolt 114. And a slope portion 119a2 and a slope portion whose inner diameter decreases from the inner peripheral end of the flat portion 119a1 and the flat portion 119b1 toward the retainer 118 than the outer diameter of the enlarged diameter portion 114a. 119b2. Accordingly, in the above-described embodiment, the flat portion 119a1 of the first annular projection 119a is plastically deformed (buckled) and comes into surface contact with the inner surface 111b of the front shell 111, thereby exhibiting sealing performance. The slope portion 119b2 of the two annular protrusions 119b is plastically deformed (depressed and deformed) and bites into the enlarged diameter portion 114a of the tie rod bolt 114 so as to exhibit sealing properties.

  As shown in FIG. 5, instead of the seal portion 119 including the first annular protrusion 119a and the second annular protrusion 119b having a trapezoidal cross-sectional shape, as shown in FIG. It is also possible to provide a seal part 160 comprising a part 160a and a second annular projection 160b. Specifically, the first annular protrusion 160a and the second annular protrusion 160b of the first modified example have an outer diameter smaller than the outer diameter of the enlarged diameter portion 114a of the tie rod bolt 114, as shown in FIGS. It has a diameter, and has a flat portion 160a1 and a flat portion 160b1 formed in a plane along the circumferential direction of the retainer 118. Further, the first annular protrusion 160a and the second annular protrusion 160b are connected to the inner peripheral ends of the flat portion 160a1 and the flat portion 160b1, and extend in the axial direction of the retainer 118 from the inner peripheral end toward the retainer 118. Along the inner surface, there are inclined portions 160a2 and 160b2 whose inner diameters are smaller than the inner diameters of the flat portions 160a1 and 160b1. Further, the first annular protrusion 160a and the second annular protrusion 160b are connected to the outer peripheral ends of the flat portion 160a1 and the flat portion 160b1, and extend from the outer peripheral end toward the retainer 118 along the axial direction of the retainer 118. It has a slope portion 160a3 and a slope portion 160b3 whose outer diameter is larger than the outside diameter of the flat portion 160a1 and the flat portion 160b1.

  As shown in FIG. 6, the negative pressure type booster 100 having the seal portion 160 configured as described above also has the master on the front shell 111 side of the tie rod bolt 114 (the front side of the booster shell 110) via the flange 116. The cylinder 21 is fastened by a nut 117. At this time, the front shell 111 is pushed toward the enlarged diameter portion 114 a of the tie rod bolt 114 by the tightening force of the nut 117.

  As a result, the flat portion 160a1 of the first annular projection 160a provided integrally with the retainer 118 is pressed by the inner surface 111b of the front shell 111, and the slope portions 160a2 and 160a3 undergo plastic deformation (buckling deformation). Thereby, it adheres to the inner surface 111b of the front shell 111 with airtightness. That is, the flat portion 160a1 of the first annular protrusion 160a constituting the seal portion 160 comes into surface contact with the inner surface 111b of the front shell 111, thereby exhibiting sealing properties. Further, the flat portion 160b1 of the second annular projection 160b provided integrally with the retainer 118 is pressed toward the side surface (the opposing surface facing the front shell 111) of the enlarged diameter portion 114a of the tie rod bolt 114, and the inclined surface portion is formed. Due to the plastic deformation (buckling deformation) of the 160b2 and the inclined surface portion 160b3, the inclined surface portion 160b3 and the side surface (opposed surface) of the enlarged diameter portion 114a are airtightly adhered. That is, the flat portion 160b1 of the second annular projection 160b constituting the seal portion 160 comes into surface contact with the side surface of the enlarged diameter portion 114a, thereby exhibiting sealing properties.

  Therefore, according to the negative pressure booster 100 in the first modified example, the outer diameter of the flat portion 160a1 and the flat portion 160b1 of the first annular protrusion 160a and the second annular protrusion 160b, which are the plastic deformation portions, is equal to the tie rod. It is set to be smaller than the outer diameter of the enlarged diameter portion 114a of the bolt 114. The slopes 160a2 and 160a3 and the slopes 160b2 and 160b3 are sandwiched between the inner surface 111b of the booster shell 110 (the front shell 111) and the enlarged diameter portion 114a of the tie rod bolt 114 and are plastically deformed. Thus, the flat portion 160a1 comes into close contact with the inner surface 111b of the booster shell 110 (the front shell 111), and the flat portion 160b1 comes into close contact with the enlarged diameter portion 114a of the tie rod bolt 114.

  According to this, the negative pressure type booster 100 is mounted on the vehicle body of the vehicle, and the master cylinder 21 is mounted on the negative pressure type booster 100, so that the slope portion 160a2 and the slope portion of the first annular projection 160a are formed. 160a3 is plastically deformed preferentially (easy), and the slope 160b2 and the slope 160b3 of the second annular projection 160b are plastically deformed. Thereby, the flat portion 160a1 of the first annular protrusion 160a can be in close contact with the inner surface 111b of the front shell 111, and the flat portion 160b1 of the second annular protrusion 160b can be in close contact with the enlarged diameter portion 114a of the tie rod bolt 114. As a result, the seal portion 160 exhibits a sealing property to hermetically seal the gap between the front shell 111 and the enlarged diameter portion 114a. Thereby, the airtightness of the negative pressure chamber R1 formed in the booster shell 110 of the negative pressure type booster 100 is sufficiently ensured. As a result, also in the first modified example, the same effect as in the above embodiment can be obtained.

(Second Modification of Embodiment)
In the above-described embodiment and the first modification, the first annular protrusion 119 a and the second annular protrusion 119 b forming the seal portion 119 or the first annular protrusion forming the seal portion 160 with respect to the retainer 118. The portion 160a and the second annular protrusion 160b are provided at only one place (one round). Instead, as shown in FIG. 7, a plurality of first annular protrusions 119a and second annular protrusions 119b, or a plurality of first annular protrusions 160a and second annular protrusions 160b are provided for the retainer 118, respectively. It is also possible to provide locations (a plurality of circumferences).

  In this case, as shown in FIG. 7, for example, a first annular protrusion 119 a and a second annular protrusion 119 b constituting the seal portion 119 are provided on the outer peripheral side of the retainer 118, and the seal portion 160 is provided on the inner peripheral side of the retainer 118. The first annular protrusion 160a and the second annular protrusion 160b that constitute the above can be provided. That is, in the second modified example, the plastically deformed portion facing the inner surface 111b of the booster shell 110 (the front shell 111) is constituted by the first annular projection 119a and the first annular projection 160a, and the tie rod bolt 114 is expanded. The plastically deformed portion facing the radial portion 114a is composed of a second annular protrusion 119b and a second annular protrusion 160b. A plurality of these plastically deformed portions (the first annular protrusion 119a and the first annular protrusion 160a, and the second annular protrusion 119b and the second annular protrusion 160b) are provided concentrically.

  As described above, even when at least one of the seal portion 119 and the seal portion 160 is provided in a plurality of places (a plurality of circumferences) concentrically with respect to the retainer 118, the provided first annular protrusion is provided. 119a and the second annular protrusion 119b, and the first annular protrusion 160a and the second annular protrusion 160b are plastically deformed by the tightening force of the nut 117. In this case, since the seal portions 119 or the seal portions 160 are provided at a plurality of locations (a plurality of circumferences) along the radial direction of the retainer 118, more airtightness can be secured. As for other effects, the same effects as those of the above embodiment can be obtained.

(Third Modification of Embodiment)
In the embodiment, the first modified example, and the second modified example, the cross-sectional shapes of the first annular protrusion 119a and the second annular protrusion 119b constituting the seal portion 119 are the same, and the seal portion 160 is formed. The first annular projection 160a and the second annular projection 160b have the same cross-sectional shape. Instead, for example, as shown in FIG. 8, for example, the seal portion 160 (that is, the first annular protrusion 160 a) is provided on an opposite surface of the retainer 118 facing the inner surface 111 b of the front shell 111, while the retainer 118 It is also possible to provide a seal portion 119 (that is, a second annular protrusion 119b) on a surface of the tie rod bolt 114 facing the enlarged diameter portion 114a.

  As described above, when the different seal portions 119 and 160 are provided for the retainer 118, the first annular protrusion 160a is pressed by the inner surface 111b of the front shell 111, and the slope portions 160a2 and 160a3 are plastically deformed. Due to the buckling deformation, the inner surface 111b of the front shell 111 is airtightly adhered. That is, the flat portion 160a1 of the first annular protrusion 160a constituting the seal portion 160 comes into surface contact with the inner surface 111b of the front shell 111, thereby exhibiting sealing properties.

  On the other hand, the second annular protrusion 119b is plastically deformed (depressed) into a concave shape when the inclined surface 119b2 is pressed against the outer peripheral end of the enlarged diameter portion 114a of the tie rod bolt 114, and the enlarged diameter portion 114a is deformed. It adheres to the outer peripheral surface with airtightness. As described above, when the slope portion 119b2 of the second annular protrusion 119b is depressed and deformed, the tie rod bolt 114 and the retainer 118 are firmly fixed and positioned. In addition, the slope 119b2 of the second annular protrusion 119b constituting the seal 119 is depressed and deformed, so that the slope 119b2 of the second annular protrusion 119b exhibits a sealing property in the direction of the axis of the tie rod bolt 114. At the same time, the tie rod bolt 114 also exhibits a sealing property in the radial direction. Therefore, also in the third modified example, the same effects as those of the above-described embodiment and each modified example can be obtained.

(Fourth modification of the embodiment)
In the above embodiment and each of the modifications, the seal portion 119 (that is, the first annular protrusion 119a and the second annular protrusion 119b) or the seal portion 160 (that is, the first annular protrusion) is provided for the retainer 118 that is the support portion. The protrusion 160a and the second annular protrusion 160b) are provided integrally. Instead, as shown in FIG. 9, for example, the sealing is performed on the facing surface of the enlarged diameter portion 114 a of the tie rod bolt 114 facing the inner surface 111 b of the front shell 111, that is, with the enlarged diameter portion 114 a as a supporting portion. The portion 160 (that is, the first annular protrusion 160a) may be provided between the inner surface 111b of the front shell 111 and the enlarged diameter portion 114a of the tie rod bolt 114.

  Also in this case, as shown in FIG. 10, the seal portion 119 and / or the seal portion 160 are plastically deformed in the same manner as in the above-described embodiment and each of the above-described modified examples along with the tightening of the nut 117, so that the front shell 111 is formed. Of the tie rod bolt 114 can be hermetically sealed. Therefore, also in the fourth modification, the same effects as those of the above embodiment and each of the above modifications can be obtained. In addition, in the fourth modification, the retainer 118 can be omitted. Thereby, the number of components constituting the negative pressure type booster 100 can be further reduced.

  In the fourth modification, the seal portion 160 is provided on the enlarged diameter portion 114a of the tie rod bolt 114 as a support portion. However, for example, the seal portion 160 (that is, the second annular protrusion 160b) is provided by using the inner surface 111b of the front shell 111 as a support portion, or the seal portion 119 (that is, the second annular protrusion 119b) is provided on the inner surface 111b of the front shell 111. ) Can also be provided.

  The implementation of the present invention is not limited to the above-described embodiment and each modified example, and various modifications are possible without departing from the purpose of the present invention.

  For example, in the above embodiment and each of the above modifications, at least one of the seal portion 119 and the seal portion 160 is provided only in the negative pressure chamber R1 formed in the booster shell 110. In addition, as shown in FIG. 11, for example, a seal portion 160 may be provided between the front shell 111 of the booster shell 110 and the flange 116.

  In the above embodiment and the first to third modifications, the seal portion 119 and the seal portion 160 are provided integrally with the retainer 118 as a support portion. In this case, in place of the retainer 118, at least one of the seal portion 119 and the seal portion 160 can be integrally provided with an annular member other than the retainer 118, for example, a washer or the like as a support portion.

  Further, in the above-described embodiment and each of the above-described modifications, at least one of the seal portion 119 and the seal portion 160 is provided integrally with the enlarged diameter portion 114a of the retainer 118 or the tie rod bolt 114. As described above, instead of being provided integrally with other members, for example, the first annular protrusion 119a and the second annular protrusion 119b constituting the seal portion 119, and the first annular protrusion 119 constituting the seal portion 160 are provided. The portion 160a and the second annular protrusion 160b may be formed separately in an annular shape. In this case, the first annular protrusion 119a and the second annular protrusion 119b in an annular shape, or the first annular protrusion 160a and the second annular protrusion 160b in an annular shape are appropriately combined to increase the diameter of the retainer 118 and the diameter. It is arranged between the portion 114a, between the retainer 118 and the front shell 111, or between the enlarged diameter portion 114a and the front shell 111. Thereby, the annular first annular protrusion 119a and the second annular protrusion 119b or the annular first annular protrusion 160a and the second annular protrusion 160b are plastically deformed at the time of tightening the nut 117, whereby The same effects as those of the embodiment and the above-described modified examples can be obtained.

DESCRIPTION OF SYMBOLS 1 ... Brake device, 2 ... Cylinder mechanism, 3 ... Actuator, 21 ... Master cylinder, 21a ... First master chamber, 21b ... Second master chamber, 22, 23 ... Master piston, 24 ... Master reservoir, 25-28 ... Wheel Cylinder, 29 brake pedal, 100 negative pressure booster, 110 booster shell, 111 front shell, 111a negative pressure inlet, 111b inner surface, 112 rear shell, 113 check valve, 114 tie rod bolt , 114a: enlarged diameter portion (supporting portion), 115: rear bolt, 116: flange, 117: nut, 118: retainer (supporting portion), 118a: through hole, 119: seal portion, 119a: first annular protrusion (plastic) Deformed portion), 119a1 flat surface portion, 119a2 inclined surface portion, 119b second annular protrusion (plastically deformed portion), 19b1 ... plane part, 119b2 ... slope part, 120 ... movable partition, 121 ... diaphragm, 121a ... outer bead part, 121b ... inner bead part, 121c ... seat part, 130 ... piston, 131 ... body part, 132 ... negative pressure connection Passage, 141 ... input shaft, 142 ... plunger, 143 ... filter, 144 ... reaction member, 145 ... output shaft, 145a ... rear cylinder, 146 ... ring member, 150 ... valve mechanism, 151 ... valve body, 160 ... Seal portion, 160a: first annular protrusion (plastically deformed portion), 160a1: flat portion, 160a2: slope portion, 160a3: slope portion, 160b: second annular protrusion (plastically deformed portion), 160b1: flat portion, 160b2 ... Slope section, 160b3 ... Slope section, B ... Boot, R1 ... Negative pressure chamber, R2 ... Transformation chamber, S1 ... Return spring, S2 ... Return splice Grayed, FL ... left front wheel, FR ... right front wheel, RL ... left rear wheel, RR ... right rear wheel

Claims (3)

A hollow booster shell,
A movable partition that hermetically partitions the booster shell into a negative pressure chamber and a variable pressure chamber,
A tie rod bolt that hermetically penetrates through the booster shell and the movable partition, fixes the booster shell to the vehicle body at one end, and supports a master cylinder at the other end. And
The tie rod bolt has an enlarged diameter portion that is enlarged so as to face an inner surface of the booster shell,
An annular member that is interposed between the inner surface of the booster shell and the enlarged portion of the tie rod bolt and is plastically deformed by being sandwiched between the inner surface of the booster shell and the enlarged portion of the tie rod bolt. It has a plastic deformation part,
The plastically deformed portion includes an annular seal portion that is in close contact with the inner surface of the booster shell and the enlarged diameter portion of the tie rod bolt ,
The seal portion,
It has an annular support portion for supporting the plastic deformation portion, and protrudes toward at least the enlarged diameter portion of the tie rod bolt among the inner surface of the booster shell and the enlarged diameter portion of the tie rod bolt. The supporting portion supports the plastic deformation portion;
The plastic deformation portion protruding toward the enlarged diameter portion of the tie rod bolt,
The tie rod bolt has a flat portion formed so that a front end side facing the enlarged diameter portion is flat in the circumferential direction, and a cross-sectional shape of a cross section in an imaginary plane including an axis has the front end side as an upper bottom. It has a slope portion connected to the flat portion so as to be trapezoidal,
The inner diameter of the flat part is set to be larger than the outer diameter of the enlarged part of the tie rod bolt, and the inner diameter of the slope part connected to the inner peripheral end of the flat part is the inner diameter of the flat part. A negative pressure booster is provided so as to have a diameter smaller than an inner diameter of the flat portion from an inner peripheral end toward the support portion . The plastically deformed portion is
Said to face the enlarged diameter portion of said inner surface or said tie rod bolts booster shell, provided more concentrically, the vacuum booster according to claim 1. The support portion is
The vacuum booster according to claim 1 or 2 , wherein the booster shell is an annular retainer interposed between the inner surface of the booster shell and the enlarged diameter portion of the tie rod bolt.

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