JP5481159B2 - Master cylinder - Google Patents

Description

  The present invention relates to a master cylinder that generates hydraulic pressure.

  Some master cylinders have a piston seal that consists of a cup seal that normally shuts off the communication between the pressure chamber that generates hydraulic pressure and the reservoir, and that supplies liquid from the reservoir to the pressure chamber when the pressure chamber becomes negative. There is a technique of forming a groove from the back surface to the outer surface of the piston seal in order to improve the liquid replenishment property of the piston seal (see, for example, Patent Document 1).

JP 2004-231093 A

  As described above, when the groove is formed from the back surface to the outer surface of the piston seal, the groove cannot be made too large in order to ensure the original sealing performance, and it is improved from the point of improving the liquid replenishment property. There was room.

  Therefore, an object of the present invention is to provide a master cylinder capable of improving the liquid replenishment property through the piston seal.

In order to achieve the above object, according to the present invention, an outer peripheral lip portion in the axial direction of the base portion of the piston seal and an inner surface on the extending side of the inner peripheral lip portion are formed in the same plane along the radial direction, A concave portion that is recessed in the axial direction from the inner surface is formed at a joint portion between the base portion and the outer peripheral lip portion .

  According to the present invention, the liquid replenishment property through the piston seal can be improved.

It is sectional drawing which shows the whole structure of the master cylinder which concerns on 1st Embodiment of this invention. It is a fragmentary sectional side view which shows the principal part of the master cylinder which concerns on 1st Embodiment of this invention. It is a fragmentary sectional side view which shows the piston seal of the master cylinder which concerns on 1st Embodiment of this invention. It is a front view which shows the piston seal of the master cylinder which concerns on 1st Embodiment of this invention. It is a fragmentary sectional view showing an important section of a master cylinder concerning a 2nd embodiment of the present invention. It is a partial side view which shows the piston seal of the master cylinder which concerns on 2nd Embodiment of this invention. It is a front view which shows the piston seal of the master cylinder which concerns on 2nd Embodiment of this invention.

  A master cylinder according to a first embodiment of the present invention will be described below with reference to FIGS.

  A master cylinder 11 according to the first embodiment shown in FIG. 1 constitutes a brake system that generates a braking force on a vehicle or the like, and corresponds to an operation amount of a brake pedal introduced via a brake booster (not shown). The brake fluid pressure is generated by force. A reservoir R for supplying and discharging brake fluid between the master cylinder 11 and the master cylinder 11 is attached to the master cylinder 11.

  The master cylinder 11 has a bottom 13 and a cylinder 14 and has a bottomed cylindrical cylinder body 15 disposed along the lateral direction, and slides toward the opening 16 side (right side in FIG. 1) of the cylinder body 15. A tandem having a primary piston (piston) 18 that is movably inserted and a secondary piston (piston) 19 that is slidably inserted to the bottom 13 side (left side in FIG. 1) of the primary piston 18 of the cylinder body 15. Of the type.

  The cylinder body 15 is formed from a single material into a bottomed cylindrical shape, and a locking protrusion 21 protruding in the axial direction is formed inside the bottom portion 13.

  In addition, the cylinder body 15 is integrally formed with a mounting base portion 22 that protrudes radially outward and extends in the axial direction, and the reservoir R is attached to both front and rear sides in the axial direction of the mounting base portion 22. The mounting holes 24 and 25 are formed so that the positions of the cylindrical portion 14 in the circumferential direction are coincident with each other. Here, the mounting seals 26 and 27 for fitting the reservoir R and sealing the gap with the reservoir R are fitted inside the mounting holes 24 and 25.

  On the inner peripheral surface 28 extending in the axial direction of the cylinder body 15, a plurality of specifically, seal peripheral grooves 30 to 33 as annular grooves recessed on the outer diameter side at four locations are shifted in the axial direction of the cylindrical portion 14. Is formed.

  The seal circumferential groove (circumferential groove) 30 closest to the bottom 13 side of the cylinder body 15 is formed close to the bottom 13 side of the mounting hole 24 on the bottom 13 side, and the seal circumferential groove 30 is made of an elastic material. A piston seal 35 is provided. The inner peripheral surface of the cylinder portion 14 is formed so that a communication hole 36 formed from the mounting hole 24 on the bottom portion 13 side is opened in the cylinder portion 14 on the opening portion 16 side of the cylinder body 15 with respect to the seal circumferential groove 30. An annular opening groove 37 that is recessed from the outer diameter side 28 is formed. Here, the opening groove 37 and the communication hole 36 mainly constitute a secondary supply path (replenishment path) 38 that connects the cylinder body 15 and the reservoir R in a communicable manner and always communicates with the reservoir R.

  A seal circumferential groove 31 is formed on the opposite side of the opening groove 37 in the cylinder body 15 with respect to the seal circumferential groove 30, that is, on the opening 16 side, and a partition seal 40 made of an elastic material is fitted into the seal circumferential groove 31. Are combined. Here, a communication groove 41 extending linearly from the seal circumferential groove 30 to the bottom 13 side is formed on the inner circumferential surface 28 of the cylindrical portion 14 so as to be recessed toward the outer diameter side. An annular large-diameter groove 42 that is recessed from the inner peripheral surface 28 of the cylindrical portion 14 to the outer diameter side is formed on the seal peripheral groove 31 side of the cylinder body 15.

  A seal circumferential groove (circumferential groove) 32 is formed closer to the opening 16 than the large-diameter groove 42 in the cylinder body 15, and a piston seal 45 made of an elastic material is fitted into the seal circumferential groove 32. On the side of the opening 16 of the seal circumferential groove 32 in the cylinder body 15, a communication hole 46 drilled from the mounting hole 25 on the side of the opening 16 is opened in the cylinder 14. An annular opening groove 47 that is recessed from the surface 28 toward the outer diameter side is formed. Here, the opening groove 47 and the communication hole 46 mainly constitute a primary supply path (replenishment path) 48 that connects the cylinder body 15 and the reservoir R so that they can communicate with each other and always communicates with the reservoir R. Further, a communication groove 49 that linearly connects the seal circumferential groove 32 and the large-diameter groove 42 is formed on the inner circumferential surface 28 of the cylindrical portion 14 so as to be recessed toward the outer diameter side.

  A seal circumferential groove 33 is formed on the cylinder body 15 on the opposite side of the opening groove 47 with respect to the seal circumferential groove 32, that is, on the opening 16 side, and a partition seal 50 made of an elastic material is fitted into the seal circumferential groove 33. Are combined.

  A primary discharge passage (discharge passage) 53 as a brake fluid discharge passage, to which a brake pipe (not shown) for supplying brake fluid to a brake device (not shown) is attached to a side portion of the cylinder portion 14 of the cylinder body 15; A secondary discharge path (discharge path) 52 is formed. The primary discharge path 53 and the secondary discharge path 52 are formed by shifting the positions in the axial direction in a state where the positions of the cylindrical portions 14 in the circumferential direction coincide with each other. 13 and the seal circumferential groove 30, and is formed at a position near the bottom 13. The other primary discharge path 53 is formed at a position near the seal circumferential groove 31 in the large-diameter groove 42. ing.

  The secondary piston 19 fitted to the bottom portion 13 side of the cylinder body 15 has a bottomed cylindrical shape having a cylindrical portion 55 and a bottom portion 56 formed on one side in the axial direction of the cylindrical portion 55. The cylinder portion 55 is inserted into the cylinder body 15 in a state where the cylinder portion 55 is disposed on the bottom 13 side of the cylinder body 15. On the opposite side of the bottom portion 56 with respect to the cylindrical portion 55, a locking projection 57 that projects in the axial direction is formed. A small-diameter inner peripheral portion 58 having a smaller diameter than the inner diameter of the cylindrical portion 55 is formed on the cylindrical portion 55 side of the bottom portion 56. Further, an annular step portion 59 having a slightly smaller diameter than the other portions is formed on the outer peripheral side of the end portion opposite to the bottom portion 56 of the cylindrical portion 55. Further, the step portion 59 of the cylindrical portion 55 is formed with a plurality of radially extending ports 60 on the bottom portion 56 side.

  Here, a portion surrounded by the bottom portion 13 of the cylinder body 15 and the bottom portion 13 side of the cylinder portion 14 and the secondary piston 19 serves as a secondary pressure chamber (pressure chamber) 63 that supplies a hydraulic pressure to the secondary discharge passage 52. Yes. The piston seal 35 provided in the seal circumferential groove 30 on the bottom 13 side of the cylinder body 15 seals between the secondary supply path 38 and the secondary pressure chamber 63 with the inner circumference slidingly contacting the outer circumference side of the secondary piston 19. Possible, that is, communication between the secondary pressure chamber 63 and the secondary supply path 38 and the reservoir R can be blocked.

  In the first embodiment, the secondary-side piston seal 35 extends substantially along the axial direction of the base 65 from the inner peripheral side of the base 65 and the base 65, as shown in FIGS. 2 to 4. An annular inner peripheral lip portion 66, and an annular outer peripheral lip portion 67 extending from the outer peripheral side of the base portion 65 to the same side as the inner peripheral lip portion 66 (in FIGS. Regarding the seal circumferential grooves 30, 32, piston seals 35, 45, supply passages 38, 48, pressure chambers 63, 86, and pistons 18, 19, the reference numerals corresponding to the secondary-side piston seal 35 are used without parentheses. The reference numerals corresponding to the primary side piston seal 45 are shown in parentheses).

  As shown in FIG. 2, the piston seal 35 comes into sliding contact with the outer peripheral surface of the secondary piston 19 at the inner peripheral lip portion 66, and comes into contact with the bottom surface 69 of the seal peripheral groove 30 of the cylinder body 15 at the outer peripheral lip portion 67. . Here, as shown in FIG. 3, the outer peripheral surface of the outer peripheral lip portion 67 is a tapered surface 67a having a diameter that increases toward the opposite side of the base 65 in the natural state. The opposite side of the base 65 is a cylindrical surface 67b having a constant diameter. Further, the inner peripheral surface of the outer peripheral lip portion 67 is a cylindrical surface 67c having a constant diameter on the base side in a natural state, and the diameter opposite to the base 65 of the cylindrical surface 67c is larger on the opposite side to the base 65. This is a tapered surface 67d.

  As shown in FIG. 2, when the secondary piston 19 is fitted inside the inner peripheral lip portion 66, the piston seal 35 is in a state along the axial direction of the base portion 65 over the entire length. In close contact with the secondary piston 19 in a slidable state. Further, in this state, the base portion 65 can come into contact with the facing surface 70 on the cylinder opening 16 side (right side in FIG. 2) of the seal circumferential groove 30 in a state of being close to the secondary piston 19 side. Further, in this state, the outer peripheral lip portion 67 has a taper surface 67 a on the base 65 side spaced from the bottom surface 69 of the seal circumferential groove 30, and a cylindrical surface 67 b on the opposite side to the base 65 has the seal circumferential groove 30. It can come into contact with the bottom surface 69. The extension length of the outer peripheral lip portion 67 is shorter than the extension length of the inner peripheral lip portion 66, and the piston seal 35 moves to the cylinder bottom 13 side (left side in FIG. 2) in the seal peripheral groove 30. However, the inner peripheral lip portion 66 first comes into contact with the passage surface 71 on the cylinder bottom 13 side of the seal peripheral groove 30, and the extended tip of the outer peripheral lip portion 67 is kept away from the passage surface 71. Is done.

  As shown in FIG. 3, the piston seal 35 has a recess 73 that is recessed in the axial direction of the piston seal 35 at least in part inside the joint 68 between the base 65 and the outer peripheral lip 67 in the present embodiment. Is formed on the entire circumference along the circumferential direction of the piston seal 35 as shown in FIG. More specifically, as shown in FIG. 3, the recess 73 is formed on the outer peripheral lip 67 side in the radial direction of the outer peripheral lip 67 in the axial direction of the base 65 and the inner surface 65 a on the extension side of the inner peripheral lip 66. Is formed so as to be recessed in the axial direction of the piston seal 35. The recess 73 has a semi-circular shape on the bottom side and two parallel straight lines on the opening side along the axial direction. The back surface 65b on the opposite side of the outer peripheral lip portion 67 and the inner peripheral lip portion 66 in the axial direction of the base portion 65 is a flat surface.

  As shown in FIG. 1, there is no input between the secondary piston 19 and the bottom portion 13 of the cylinder body 15 from the brake pedal side (the right side in FIG. 1) (not shown). A secondary piston spring 78 is provided to determine the distance between the position and the position). One end of the secondary piston spring 78 is locked by disposing the locking protrusion 21 of the cylinder bottom 13 on the inner side, and the other end passes through the cylindrical portion 55 of the secondary piston 19 and has a small diameter inner periphery of the bottom 56. Locked to the portion 58.

  The primary piston 18 fitted to the opening 16 side of the cylinder body 15 includes a first cylindrical portion 80, a bottom portion 81 formed on one side in the axial direction of the first cylindrical portion 80, and a first cylinder of the bottom portion 81. It has a shape having a second cylindrical portion 82 formed on the opposite side to the portion 80, and is inserted into the cylinder body 15 with the first cylindrical portion 80 disposed on the secondary piston 19 side. Here, an output shaft of a brake booster (not shown) is inserted inside the second cylindrical portion 82, and this output shaft presses the bottom portion 81.

  On the outer peripheral side of the end opposite to the bottom 81 of the first cylindrical portion 80, an annular recess 83 having a slightly smaller diameter than the other portions is formed. Furthermore, a plurality of ports 84 are formed radially in the concave portion 83 of the first cylindrical portion 80 so as to penetrate in the radial direction on the bottom 81 side.

  Here, a portion surrounded by the opening 16 side of the cylinder portion 14 of the cylinder body 15, the primary piston 18, and the secondary piston 19 is a primary pressure chamber (pressure chamber) 86 that supplies hydraulic pressure to the primary discharge path 53. It has become. The piston seal 45 provided in the seal circumferential groove 32 of the cylinder body 15 can seal the space between the primary replenishment passage 48 and the primary pressure chamber 86 by sliding the inner circumference to the outer circumference side of the primary piston 18. Communication between the primary pressure chamber 86 and the primary supply path 48 and the reservoir R can be blocked.

  In the first embodiment, the piston seal 45 is the same as the piston seal 35 as shown in FIGS. 2 to 4 (in FIGS. 2 to 4, the seal circumferential grooves 30 and 32, the piston Regarding the seals 35 and 45, the replenishment paths 38 and 48, the pressure chambers 63 and 86, and the pistons 18 and 19, the reference numerals corresponding to the piston seal 45 are shown in parentheses). That is, the piston seal 45 also has a base portion 65, an inner peripheral lip portion 66, and an outer peripheral lip portion 67. The outer peripheral lip portion 67 has a tapered surface 67a, a cylindrical surface 67b, a cylindrical surface 67c, and a tapered surface 67d. A recess 73 is formed inside the joint 68 between the base 65 and the outer peripheral lip 67.

  As shown in FIG. 2, the piston seal 45 comes into sliding contact with the outer peripheral surface of the primary piston 18 at the inner peripheral lip portion 66, and comes into contact with the bottom surface 69 of the seal peripheral groove 32 of the cylinder body 15 at the outer peripheral lip portion 67. .

  As shown in FIG. 2, when the primary piston 18 is fitted inside the inner peripheral lip portion 66, the piston seal 45 is in a state along the axial direction of the base portion 65 over almost the entire length. The primary piston 18 is slidably contacted. Further, in this state, the base portion 65 can come into contact with the facing surface 70 on the cylinder opening 16 side (right side in FIG. 2) of the seal circumferential groove 32 in a state of being close to the primary piston 18 side. Further, in this state, the outer peripheral lip portion 67 has a taper surface 67 a on the base 65 side spaced from the bottom surface 69 of the seal circumferential groove 32, and a cylindrical surface 67 b on the opposite side to the base 65 has the seal circumferential groove 32. It can come into contact with the bottom surface 69. The extension length of the outer peripheral lip portion 67 is shorter than the extension length of the inner peripheral lip portion 66, and the piston seal 45 moves to the cylinder bottom 13 side (left side in FIG. 2) in the seal peripheral groove 32. Even so, the inner peripheral lip portion 66 first comes into contact with the passage surface 71 on the cylinder bottom 13 side of the seal peripheral groove 32, and the extended tip of the outer peripheral lip portion 67 is maintained in a separated state with respect to the passage surface 71. Is done.

  As shown in FIG. 1, the partition seal 40 provided in the seal circumferential groove 31 is in sliding contact with the secondary piston 19 to always seal between the secondary pressure chamber 63 and the primary pressure chamber 86. The partition seal 50 provided at 33 is in sliding contact with the primary piston 18 to always seal the primary pressure chamber 86 against the outside air.

  Between the secondary piston 19 and the primary piston 18, a primary piston spring 88 and an interval adjusting unit 89 are provided for determining the interval in an initial state where there is no input from a brake pedal side (right side in FIG. 1) not shown. Yes. That is, the primary piston spring 88 urges the secondary piston 19 and the primary piston 18 in the separating direction, and the interval adjusting unit 89 regulates the separation exceeding the set interval between the secondary piston 19 and the primary piston 18. Here, the gap adjusting portion 89 is fixed to the retainer 91 that contacts the bottom portion 56 of the secondary piston 19, the retainer 92 that contacts the bottom portion 81 of the primary piston 18, and the retainer 91, and is slidable within a predetermined range with respect to the retainer 92. A primary piston spring 88 is interposed between the retainers 91 and 92 on both sides. The retainer 91 is locked to the locking protrusion 57 of the secondary piston 19.

  Here, as shown in FIG. 2, when the hydraulic pressure in the secondary pressure chamber 63 is equal to or higher than the hydraulic pressure on the secondary supply path 38 side, that is, on the reservoir R side, the outer peripheral lip 67 is removed by pressure. The communication between the secondary pressure chamber 63, the secondary supply path 38, and the reservoir R is cut off by being pushed out to the radial side and in close contact with the bottom surface 69 of the seal circumferential groove 30. On the other hand, when the hydraulic pressure in the secondary pressure chamber 63 is lower than the hydraulic pressure on the secondary supply path 38 side, that is, on the reservoir R side, the outer peripheral lip portion 67 is compressed and contracted to the inner diameter side by the hydraulic pressure. 69, the gap 76 between the bottom surface 69 of the seal circumferential groove 30 and the outer peripheral lip portion 67 of the piston seal 35, and the gap 74 between the opposing surface 70 of the seal circumferential groove 30 and the back surface 65b of the piston seal 35, Via the gap 75 between the cylinder body 15 and the secondary piston 19, the secondary pressure chamber 63, the secondary supply path 38, and the reservoir R are communicated to allow the secondary pressure chamber 63 to be supplied with liquid from the reservoir R. .

  Similarly, when the hydraulic pressure in the primary pressure chamber 86 is equal to or higher than the hydraulic pressure on the primary replenishment passage 48 and the reservoir R side, the outer peripheral lip portion 67 is pushed and expanded toward the outer diameter side by the pressure. By contacting the bottom surface 69 of the seal circumferential groove 32, communication between the primary pressure chamber 86, the primary supply chamber 48 and the reservoir R is blocked. On the other hand, when the hydraulic pressure in the primary pressure chamber 86 is lower than the hydraulic pressure on the primary supply path 48 and the reservoir R side, the outer peripheral lip portion 67 is compressed and contracted to the inner diameter side by the hydraulic pressure, and the bottom surface 69 of the seal peripheral groove 32. The clearance 76 between the bottom surface 69 of the seal circumferential groove 32 and the outer peripheral lip 67 of the piston seal 45, the clearance 74 between the opposing surface 70 of the seal circumferential groove 32 and the back surface 65b of the piston seal 45, and the cylinder Via the gap 75 between the main body 15 and the primary piston 18, the primary pressure chamber 86, the primary supply path 48, and the reservoir R are communicated to allow the primary pressure chamber 86 to be replenished from the reservoir R.

  Next, the operation of the master cylinder will be described.

  As shown in FIG. 1, the primary piston 18 in the initial position communicates the primary replenishment path 48 and the primary pressure chamber 86 by the port 84, and as a result, communicates the primary pressure chamber 86 to the reservoir R. I am letting.

  From this state, when there is a brake operation input, the primary piston 18 moves to the bottom 13 side of the cylinder body 15 and the port 84 is positioned closer to the bottom 13 than the piston seal 45, the hydraulic pressure in the primary pressure chamber 86 changes to the reservoir R side. The piston seal 45 comes into close contact with the bottom surface 69 of the seal circumferential groove 32 at the outer peripheral lip portion 67, and the communication between the primary pressure chamber 86, the primary supply path 48 and the reservoir R is blocked. As a result, the primary piston 18 further moves toward the cylinder bottom 13, whereby brake fluid is supplied from the primary pressure chamber 86 to the brake device (not shown) via the primary discharge path 53.

  On the other hand, when the brake operation input is released from this state and the hydraulic pressure in the primary pressure chamber 86 becomes lower than the hydraulic pressure on the primary supply path 48 and the reservoir R side, the outer peripheral lip portion 67 of the piston seal 45 has an inner diameter due to the hydraulic pressure. And is separated from the bottom surface 69 of the seal circumferential groove 32, so that the primary supply passage 48 of the cylinder body 15 has a gap 75 between the cylinder body 15 and the primary piston 18, and a back surface 65 b of the piston seal 45. The brake fluid is communicated to the primary pressure chamber 86 through the gap 74 between the opposed surface 70 of the seal circumferential groove 32 and the gap 76 between the outer peripheral lip portion 67 and the bottom surface 69 of the seal circumferential groove 32, and brake fluid is supplied from the reservoir R to the primary pressure. Supply to chamber 86. At this time, since the concave portion 73 is formed inside the joint portion 68 between the base portion 65 of the piston seal 45 and the outer peripheral lip portion 67 and the bending rigidity of the root portion of the outer peripheral lip portion 67 is reduced, the outer peripheral lip The portion 67 is easily compressed toward the inner diameter side and is separated from the bottom surface 69 of the seal circumferential groove 32. As a result, the primary piston 18 immediately returns to the cylinder opening 16 side.

  Further, the secondary piston 19 in the initial position communicates the secondary supply passage 38 and the secondary pressure chamber 63 via the port 60, and as a result, communicates the secondary pressure chamber 63 to the reservoir R. .

  From this state, when there is a brake operation input and the primary piston 18 moves to the bottom 13 side, it is pressed through the primary piston spring 88, the secondary piston 19 moves to the bottom 13 side of the cylinder body 15, and the port 60 When positioned closer to the bottom 13 side of the cylinder body 15 than the piston seal 35, the hydraulic pressure in the secondary pressure chamber 63 becomes equal to or higher than the hydraulic pressure on the reservoir R side, and the piston seal 35 is at the bottom surface of the seal circumferential groove 30 at the outer peripheral lip portion 67. 69, and the communication between the secondary pressure chamber 63 and the secondary supply path 38 and the reservoir R is cut off. As a result, the secondary piston 19 further moves to the cylinder bottom portion 13 side, thereby causing the secondary pressure chamber 63 to move away from the secondary pressure chamber 63. Brake fluid is supplied to a brake device (not shown) via the secondary discharge passage 52 That.

  On the other hand, when the brake operation input is released from this state and the hydraulic pressure in the secondary pressure chamber 63 becomes lower than the hydraulic pressure on the secondary supply path 38 and the reservoir R side, the outer peripheral lip portion 67 of the piston seal 35 has an inner diameter due to the hydraulic pressure. And is separated from the bottom surface 69 of the seal circumferential groove 30, so that the secondary supply path 38 of the cylinder body 15 includes a gap 75 between the cylinder body 15 and the secondary piston 19, and a back surface 65 b of the piston seal 35. The brake fluid is supplied from the reservoir R to the secondary pressure via the gap 74 between the opposed surface 70 of the seal circumferential groove 30 and the gap 76 between the outer peripheral lip 67 and the bottom surface 69 of the seal circumferential groove 30 to communicate with the secondary pressure chamber 63. Supply to chamber 63. At this time, since the concave portion 73 is formed inside the joint portion 68 between the base portion 65 of the piston seal 35 and the outer peripheral lip portion 67 and the bending rigidity of the base portion of the outer peripheral lip portion 67 is lowered, the outer peripheral lip The portion 67 is easily compressed toward the inner diameter side and is separated from the bottom surface 69 of the seal circumferential groove 30. As a result, the secondary piston 19 immediately returns to the cylinder opening 16 side.

  According to the master cylinder of the first embodiment described above, the concave portion 73 is formed inside the joint portion 68 between the base portion 65 and the outer peripheral lip portion 67 of the piston seals 35, 45. Since the bending rigidity of the root portion that most contributes to the falling rigidity of the lip portion 67 is reduced, when a differential pressure is generated between the secondary pressure chamber 63, the primary pressure chamber 86, and the reservoir R, the secondary pressure chamber is supplied from the reservoir R to the secondary pressure chamber. 63 and the primary pressure chamber 86 through the piston seals 35 and 45 can be improved.

  Further, the recess 73 is formed on the entire circumference along the circumferential direction of the piston seals 35 and 45, and further reduces the bending rigidity of the root portion of the outer peripheral lip 67. The liquid replenishment property can be further improved.

  Moreover, the recessed part 73 of the piston seals 35 and 45 can be formed by the conventional manufacturing method, and can be formed at low cost.

  A plurality of annular recesses 73 may be formed concentrically. Moreover, you may form the recessed part 73 in circular arc shape in part along the circumferential direction of the piston seals 35 and 45, and in that case, for example, it may form multiple in the circumferential direction intermittently at equal intervals, etc. Is possible. In such a configuration, the bending rigidity of only a part of the outer peripheral lip portion 67 where the concave portion 73 is formed is lowered, and when the brake is released, the outer peripheral lip portion 67 and the bottom surfaces 69 of the seal peripheral grooves 30, 32 As a result, the surface pressure of the surface is uneven, and a line contact state that is easy to open can be effectively generated from a surface contact state that is difficult to open.

  Next, a master cylinder according to a second embodiment of the present invention will be described with reference to FIGS. 5 to 7 focusing on differences from the first embodiment. In addition, the same code | symbol is attached | subjected to the part similar to 1st Embodiment, and the description is abbreviate | omitted.

  In the second embodiment, piston seals 35 and 45 are different from the first embodiment. That is, as shown in FIGS. 5 to 7, in the second embodiment, the secondary side piston seal 35 (in FIGS. 5 to 7, the seal circumferential grooves 30 and 32, the piston seals 35 and 45, the supply passages 38 and 48). For the pressure chambers 63 and 86 and the pistons 18 and 19, the reference numerals corresponding to the secondary-side piston seal 35 are indicated without parentheses, and the reference numerals corresponding to the primary-side piston seal 45 described later are indicated with parentheses. The inner peripheral surface of the outer peripheral lip portion 67 is a tapered surface 67d whose diameter increases toward the opposite side of the base portion 65 throughout.

  As shown in FIGS. 5 and 6, the piston seal 35 is recessed at least in part inside the joint portion 68 between the base portion 65 and the outer peripheral lip portion 67, and is recessed in the axial direction at the base portion 65 and at the outer peripheral lip portion 67. As shown in FIG. 7, a plurality of recesses 95 that are recessed in the radial direction are formed at predetermined equal intervals in the circumferential direction of the piston seal 35. More specifically, as shown in FIG. 5, these concave portions 95 extend linearly along the radial direction on the inner peripheral lip portion 66 and the inner surface 65 a of the outer peripheral lip portion 67 on the extending side of the base portion 65. A base groove 96 formed in such a manner, and an outer peripheral lip groove 97 formed so as to extend linearly along the axial direction on the tapered surface 67d of the outer peripheral lip part 67 continuously to the base groove 96. have. The back surface 65b on the opposite side of the outer peripheral lip portion 67 and the inner peripheral lip portion 66 in the axial direction of the base portion 65 is a flat surface.

  Therefore, as in the first embodiment, when the hydraulic pressure in the secondary pressure chamber 63 becomes lower than the hydraulic pressure on the secondary supply path 38 and the reservoir R side, the outer peripheral lip 67 of the piston seal 35 is compressed toward the inner diameter side by the hydraulic pressure. However, a recess 95 comprising a base groove 96 and an outer peripheral lip groove 97 is formed on the inner side of the joint 68 between the base 65 and the outer peripheral lip 67 of the piston seal 35. Since the bending rigidity of the outer peripheral lip portion 67 and the base portion 65 is reduced, the outer peripheral lip portion 67 is easily compressed toward the inner diameter side and separated from the bottom surface 69 of the seal peripheral groove 30 and the base portion 65. Is easily deformed so as to be drawn toward the inner diameter side and is separated from the facing surface 70 of the seal circumferential groove 30. Therefore, the secondary supply path 38 of the cylinder body 15 includes a gap 75 between the cylinder body 15 and the secondary piston 19, a gap 74 between the back surface 65 b of the piston seal 35 and the opposed surface 70 of the seal circumferential groove 30, and an outer peripheral lip portion 67. The secondary pressure chamber 63 communicates with the secondary pressure chamber 63 through the gap 76 between the seal circumferential groove 30 and the bottom surface 69 of the seal circumferential groove 30 to smoothly supply brake fluid from the reservoir R to the secondary pressure chamber 63.

  Also in the second embodiment, the piston seal 45 is the same as the piston seal 35 as shown in FIGS. 5 to 7 (in FIGS. The piston seals 35 and 45, the supply passages 38 and 48, the pressure chambers 63 and 86, and the pistons 18 and 19 are indicated by parentheses in the reference numerals corresponding to the primary-side piston seal 45). That is, the piston seal 45 also has a base portion 65, an inner peripheral lip portion 66, and an outer peripheral lip portion 67, and the outer peripheral lip portion 67 has a tapered surface 67a, a cylindrical surface 67b, and a tapered surface 67d. A concave portion 95 composed of a base groove 96 and an outer peripheral lip groove 97 is formed inside the joint 68 between the base 65 and the outer peripheral lip 67.

  Therefore, when the hydraulic pressure in the primary pressure chamber 86 becomes lower than the hydraulic pressure on the primary supply path 48 and the reservoir R side, the outer peripheral lip portion 67 of the piston seal 45 is compressed toward the inner diameter side by the hydraulic pressure, and the seal peripheral groove 32 A recess 95 comprising a base groove 96 and an outer peripheral lip groove 97 is formed on the inner side of the joint 68 between the base 65 of the piston seal 45 and the outer peripheral lip 67. Since the bending rigidity of the portion 67 and the base portion 65 is lowered, the outer peripheral lip portion 67 is easily compressed toward the inner diameter side so as to be separated from the bottom surface 69 of the seal circumferential groove 32 and the base portion 65 is drawn into the inner diameter side. It is easily deformed to be separated from the facing surface 70 of the seal circumferential groove 32. Therefore, the primary supply path 48 of the cylinder body 15 includes a gap 75 between the cylinder body 15 and the primary piston 18, a gap 74 between the back surface 65 b of the piston seal 45 and the facing surface 70 of the seal circumferential groove 32, and an outer peripheral lip portion 67. The brake fluid is smoothly supplied from the reservoir R to the primary pressure chamber 86 by communicating with the primary pressure chamber 86 through a gap 76 between the seal circumferential groove 32 and the bottom surface 69 of the seal circumferential groove 32.

  According to the second embodiment having such a configuration, the concave portion 95 is formed inside the joint portion 68 between the base portion 65 of the piston seals 35 and 45 and the outer peripheral lip portion 67, so that the bending rigidity of the outer peripheral lip portion 67 is increased. Therefore, as in the first embodiment, when a differential pressure is generated in the secondary pressure chamber 63, the primary pressure chamber 86, and the reservoir R, the pressure from the reservoir R to the secondary pressure chamber 63 and the primary pressure chamber 86 is reduced. The liquid replenishment property through the piston seals 35 and 45 can be improved.

  In addition, the recess 95 is continuous with the base groove 96 extending linearly along the radial direction on the surface 65 a in the extending direction of the inner peripheral lip 66 and the outer peripheral lip 67 of the base 65, and the base groove 96. Since the taper surface 67d of the outer peripheral lip portion 67 has the outer peripheral lip portion groove 97 extending linearly along the axial direction, the bending rigidity of the base portion 65 can be reduced in addition to the outer peripheral lip portion 67. The amount of liquid at the time of liquid replenishment can be ensured by these being greatly bent.

  In the above-described embodiment, the base groove extends so as to extend linearly along the radial direction of the piston seals 35 and 45 on the inner surface 65a of the inner peripheral lip portion 66 and the outer peripheral lip portion 67 of the base portion 65. However, the present invention is not limited to this, and it may be formed in a curved shape, a circular shape, or an elliptical shape. The outer peripheral lip portion groove 97 is formed on the tapered surface 67d of the outer peripheral lip portion 67 so as to extend linearly along the axial direction of the piston seals 35 and 45. However, the present invention is not limited to this. The outer peripheral lip groove 97 may be formed so as to be inclined with respect to the axial direction of 45, 45, or the outer peripheral lip groove 97 may be formed in a curved shape so as to intersect the axial direction of the piston seals 35, 45. You may do it.

11 Master cylinder 15 Cylinder body 18 Primary piston (piston)
19 Secondary piston (piston)
28 Inner peripheral surface 30 Seal circumferential groove (circumferential groove)
32 Seal circumferential groove (circumferential groove)
35, 45 Piston seal 38 Secondary supply path (supply path)
48 Primary supply path (supply path)
52 Secondary discharge path (discharge path)
53 Primary discharge path (discharge path)
63 Secondary pressure chamber (pressure chamber)
65 Base portion 66 Inner peripheral lip portion 67 Outer peripheral lip portion 68 Joint portion 73, 95 Recessed portion 86 Primary pressure chamber (pressure chamber)
96 Base groove 96
97 Outer lip groove R Reservoir

Claims (3)

A cylinder body having a brake fluid discharge path and a replenishment path communicating with the reservoir and formed of a single material in a cylindrical shape with a bottom; and a cylinder body slidably inserted into the cylinder body, A piston that forms a pressure chamber that supplies hydraulic pressure to the discharge passage, and an inner periphery that is provided in a circumferential groove formed in the cylinder body so that the inner periphery is in sliding contact with the piston. In the master cylinder having a piston seal capable of sealing between, the cylinder body is formed as an annular groove in which the circumferential groove is recessed to the outer diameter side on the inner circumferential surface extending in the axial direction.
The piston seal includes an annular base portion, an inner peripheral lip portion that extends from the inner peripheral side of the base portion and slidably contacts the outer peripheral surface of the piston, and extends from the outer peripheral side of the base portion to the peripheral portion of the cylinder body. An outer peripheral lip portion in contact with the groove, and an inner surface on the extending side of the outer peripheral lip portion and the inner peripheral lip portion in the axial direction of the base portion is formed in the same plane along a radial direction, A master cylinder , wherein a concave portion recessed in an axial direction from the inner surface is formed at a joint portion between a base portion and the outer peripheral lip portion .   2. The master cylinder according to claim 1, wherein the recess is formed on the entire circumference or a part along a circumferential direction of the piston seal.   The concave portion includes a base groove extending linearly along a radial direction on a surface of the base portion in the extending direction of the inner peripheral lip portion and the outer peripheral lip portion, and the outer peripheral lip portion continuous with the base groove. The master cylinder according to claim 1, further comprising an outer peripheral lip groove extending linearly along the axial direction.

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