JP4784744B2 - Seal structure - Google Patents

Description

  The present invention relates to a seal structure for an inner peripheral portion of a cancel plate in an automatic transmission piston mechanism.

  In an automatic transmission (A / T) of a vehicle such as an automobile, a hydraulically operated piston mechanism is provided to turn on / off the clutch, and this piston mechanism cancels centrifugal hydraulic pressure. Therefore, a cancel plate (also referred to as a canceller seal) is provided.

  FIG. 5 shows an example of this type of piston mechanism 1, and a cancel plate 4 is a piston (also referred to as a bonded piston seal) inside the housing 2 and on the outer peripheral side (right side in the drawing) of the housing shaft portion 3. 5. It is incorporated together with the multi-plate clutch 6, the return spring 7, and the like. The housing shaft 3 is provided with an oil supply port 9 for supplying oil to the hydraulic chamber 8 so as to move the piston 5 toward the multi-plate clutch 6, and an oil supply port for the sub hydraulic chamber 10. 11 and an oil discharge port 12 are provided.

  The cancel plate 4 is formed in an annular shape by pressing a sheet metal or the like. The cancel plate 4 is disposed on the outer peripheral side of the housing shaft portion 3 and is attached to a mounting groove 13 provided on the outer peripheral surface of the housing shaft portion 3. 14, holding the return spring 7.

  Further, an outer peripheral side sealing elastic body 16 slidably in close contact with the inner peripheral surface of the clutch pressing portion 15 of the piston 5 is attached to the outer peripheral end portion of the cancel plate 4. An inner peripheral side sealing elastic body 17 that is in close contact with the outer peripheral surface of the housing shaft portion 3 is attached to the peripheral end portion. The inner peripheral side elastic body 17 for sealing may not be provided depending on product specifications, but the present invention is intended for the case where it is provided.

  The inner peripheral sealing elastic body 17 includes a lip type shown in FIG. 6 and a fitting type shown in FIG.

  The lip-type sealing elastic body 17 shown in FIG. 6 includes an inner peripheral surface application portion 17 a attached to the inner peripheral surface 4 a of the cancel plate 4 and an end surface cover attached to the axial end surface 4 b of the cancel plate 4. A seal lip 17c that is in close contact with the outer peripheral surface of the shaft portion 3 is formed integrally with the latter end face application site 17b. Accordingly, the inner diameter dimension φA of the seal lip 17c is set smaller than the outer diameter dimension φB of the shaft portion 3, whereas the inner diameter dimension φC of the inner peripheral surface attachment portion 17a is the outer diameter size of the shaft portion 3. It is set larger than φB.

  The fitting-type sealing elastic body 17 shown in FIG. 7 includes an inner peripheral surface attachment portion 17 a attached to the inner peripheral surface 4 a of the cancel plate 4 and an end face attached to the axial end surface 4 b of the cancel plate 4. The attachment part 17 b is integrally formed, and both the attachment parts 17 a and 17 b are directly fitted to the outer peripheral surface of the shaft portion 3. Accordingly, the inner diameter dimension φD of both the adhesion portions 17 a and 17 b is set smaller than the outer diameter dimension φB of the shaft portion 3.

  However, the conventional seal structure has the following disadvantages.

  That is, in the lip type sealing elastic body 17 of FIG. 6, the inner peripheral surface application portion 17a having a predetermined radial thickness e is attached to the inner peripheral surface 4a of the cancel plate 4, and this inner peripheral surface. Since the radial gap f is set between the deposition site 17a and the shaft portion 3, there is a relatively large dimensional difference h between the inner diameter size φG of the cancel plate 4 and the outer diameter size φB of the shaft portion 3. Is set. Therefore, the cancel plate 4 tends to be eccentric with respect to the shaft portion 3 due to this large dimensional difference h. Wear may occur, or the centrifugal oil pressure cancellation effect may be adversely affected. Since the inner peripheral surface attachment portion 17a made of a rubber-like elastic body is sandwiched between the cancel plate 4 and the shaft portion 3 and compressed in the radial direction, it is difficult to become an eccentricity prevention material.

  Further, in the fitting-type sealing elastic body 17 shown in FIG. 7, the inner peripheral surface attaching portion 17a having a predetermined radial thickness e is also attached to the inner peripheral surface 4a of the cancel plate 4. A relatively large dimensional difference h is set between the inner diameter dimension φG of the cancel plate 4 and the outer diameter dimension φB of the shaft portion 3. Therefore, it is the same as the lip type that the cancel plate 4 is easily eccentric with respect to the shaft portion 3 due to this large dimensional difference h.

  Further, in this fitting type, since the inner diameter dimension φD of the entire sealing elastic body 17 is set smaller than the outer diameter dimension φB of the shaft portion 3, when the cancel plate 4 is mounted on the shaft portion 3. Needs to slide the sealing elastic body 17 in the axial direction on the peripheral surface of the shaft portion 3. Among the elastic body 17 for sealing, the inner peripheral surface attaching portion 17a is held by the metallic cancel plate 4 on the back side (outer peripheral side), and therefore, it is difficult to escape radially outward. However, since the mounting groove 13 for mounting the snap ring 14 is provided on the outer peripheral surface of the shaft portion 3 as described above, the sealing elastic body 17 must pass through the mounting groove 13 during mounting. Accordingly, the cancel plate 4 having the sealing elastic body 17 that has an interference fit with the shaft portion 3 and is difficult to escape radially outward is forcibly passed through the mounting groove 13, and thus is difficult to pass. There is a disadvantage that the wearability is not so good. In addition, the sealing elastic body 17 may be damaged by the edge portion of the mounting groove 13 when passing, and if it is damaged, the sealing effect may be impaired.

JP 2002-139155 A JP-A-11-257374

  In view of the above points, the present invention can effectively suppress the eccentricity of the cancel plate with respect to the shaft portion, and also has a seal structure in which the cancel plate is easily mounted on the shaft portion provided with the snap ring mounting groove. The purpose is to provide.

In order to achieve the above object, a seal structure according to claim 1 of the present invention is a seal structure of an inner peripheral portion of a cancel plate in a piston mechanism for an automatic transmission, and includes a cancel plate disposed on the outer peripheral side of a shaft portion, An elastic body for sealing that is attached to a mounting groove provided in the shaft portion and holds the cancel plate, and is attached to an inner peripheral end portion of the cancel plate and is in close contact with the shaft portion The sealing elastic body is attached only to the end surface in the axial direction of the inner peripheral end of the cancel plate, and the inner surface of the cancel plate is provided with the cancel plate. The metal part which is a material is provided with the eccentric regulation part which directly faces the said shaft part.

  The seal structure according to claim 2 of the present invention is the seal structure according to claim 1 described above, wherein the sealing elastic body has an unbonded portion with respect to the cancel plate, and is bent at the unbonded portion when mounted. It is characterized by that.

  The seal structure according to claim 3 of the present invention is the seal structure according to claim 1 described above, wherein the cancel plate includes a snap ring mounted in a mounting groove provided in the shaft portion and a step portion provided in the shaft portion. The sealing elastic body is characterized in that its inner diameter dimension is set larger than the inner diameter dimension of the cancel plate and is in close contact with the large-diameter side peripheral surface of the stepped portion.

  In the sealing structure according to the first aspect of the present invention having the above-described configuration, the sealing elastic body is attached only to the axial end surface of the cancel plate and is not attached to the inner peripheral surface of the cancel plate. On the inner peripheral surface of the cancel plate, there is provided an eccentricity restricting portion having a structure in which the metal portion, which is the material of the plate, directly faces the shaft portion. It functions as a radial stopper that suppresses the radial displacement of the plate. Since the sealing elastic body is not attached to the inner peripheral surface of the cancel plate, the inner diameter dimension of the cancel plate can be close to the outer diameter dimension of the shaft portion.

  In addition, since the sealing elastic body attached only to the axial end surface of the cancel plate is not held by the rigid material on the back side (outer peripheral side), it is possible to escape radially outward. . Therefore, the sealing elastic body can escape radially outward even when passing through the snap ring mounting groove during mounting.

  Further, this ease of escape can also be obtained by providing a non-adhered portion with respect to the cancel plate on the sealing elastic body to cause bending at the time of mounting (claim 2).

  In addition, the reason why the cancel plate was not so easy to mount on the shaft part provided with the snap ring mounting groove was because the sealing elastic body was easily caught in the mounting groove during mounting. The reason why it was easy to be caught is that the inner diameter of the sealing elastic body was set smaller than the outer diameter of the shaft portion provided with the mounting groove. Therefore, if the inner diameter dimension of the sealing elastic body is set larger than the outer diameter dimension of the shaft portion provided with the mounting groove, the sealing elastic body will not be caught by the mounting groove. However, in this case, since the sealing elastic body does not contact the shaft portion, the sealing effect cannot be achieved. Therefore, in the present invention, a step portion is provided on the outer periphery of the shaft portion, the cancel plate is mounted between the snap ring and the step portion, and the sealing elastic body is brought into close contact with the large-diameter side peripheral surface of the step portion. (Claim 3). According to this configuration, since the inner diameter dimension of the sealing elastic body is set larger than the outer diameter dimension of the shaft portion provided with the mounting groove, the sealing elastic body is not caught in the mounting groove, and the seal Since the elastic body for use is in close contact with the large-diameter side peripheral surface of the stepped portion, a sealing effect can be achieved.

  The present invention has the following effects.

  That is, in the sealing structure according to claim 1 of the present invention, the sealing elastic body is attached only to the axial end surface of the cancel plate and is not attached to the inner peripheral surface of the cancel plate. Is provided with an eccentricity restricting portion in which the metal portion, which is the material of the plate, directly faces the shaft portion, so that this eccentricity restricting portion abuts the shaft portion and suppresses the radial displacement of the cancel plate. Functions as a direction stopper. Since the sealing elastic body is not attached to the inner peripheral surface of the cancel plate, the inner diameter of the cancel plate can be made close to the outer diameter of the shaft portion. Therefore, it is possible to effectively suppress the cancel plate from being eccentric with respect to the shaft portion by the radial stopper function exhibited by the eccentricity restricting portion.

  In addition, the sealing elastic body attached only to the axial end face of the cancel plate is not held by the rigid material on the back side (outer peripheral side), so it is possible to escape outward in the radial direction. Sometimes it is possible to escape radially outward even when passing through the snap ring mounting groove. Therefore, the ease of escape makes it difficult for the sealing elastic body to be caught in the mounting groove, so that the mounting property of the cancel plate to the shaft portion provided with the snap ring mounting groove can be improved.

  In addition to this, in the sealing structure according to claim 2 of the present invention, the elastic member for sealing is provided with a non-bonded portion with respect to the cancel plate, and is configured to bend at the time of mounting. Even if it escapes, the elastic body for sealing is not easily caught in the mounting groove. Therefore, it is possible to further improve the mountability of the cancel plate to the shaft portion provided with the snap ring mounting groove.

  In the seal structure according to claim 3 of the present invention, the cancel plate is mounted between the snap ring mounted in the mounting groove provided in the shaft portion and the stepped portion provided in the shaft portion, and the sealing elastic body. Since the inner diameter is set to be larger than the inner diameter of the cancel plate and is in close contact with the large-diameter side peripheral surface of the stepped portion, the sealing elastic body does not get caught in the mounting groove, and It is possible to ensure a sealing effect. Therefore, also with this configuration, it is possible to improve the mountability of the cancel plate to the shaft portion provided with the snap ring mounting groove.

The present invention includes the following embodiments.
(1) A structure in which the elastic body for sealing the inner periphery of the cancel plate is disposed only on the upper part of the metal part.
(2) A structure in which the inner diameter of the metal part and the outer diameter of the shaft are close to each other to reduce the eccentricity of the seal.
(3) A structure in which a part of the elastic body at the upper part of the metal part has an unbonded region with the metal part, and the elastic body bends when mounted.
(4) A structure in which any two or all of the above (1) to (3) are combined.

  As described above, the cancel plate may be referred to as a canceller seal or the like.

  Next, embodiments of the present invention will be described with reference to the drawings.

First embodiment ...
FIG. 1 shows a cross section of a seal structure according to a first embodiment of the present invention. The first embodiment is an embodiment of the invention according to claim 1 of the present application.

  The seal structure according to this embodiment is a structure that seals the inner peripheral portion of the cancel plate 4 in the piston mechanism for an automatic transmission, and the cancel plate 4 disposed on the outer peripheral side of the shaft portion 3 and the shaft portion 3. And a snap ring 14 that is mounted in a mounting groove 13 provided on the outer peripheral surface and holds the cancel plate 4. The cancel plate 4 is attached to the inner peripheral end of the cancel plate 4 and is outer peripheral surface of the shaft portion 3. A sealing elastic body 17 is provided so as to be in close contact therewith.

  The sealing elastic body 17 is a lip type sealing elastic body, and is not attached to the inner peripheral surface 4a of the cancel plate 4 but only to the axial end face 4b. Is integrally provided with an end surface adhering portion 17b attached to the axial end surface 4b of the cancel plate 4 and a seal lip 17c formed integrally with the end surface adhering portion 17b and in close contact with the outer peripheral surface of the shaft portion 3. is doing. The seal lip 17 c is set to have an inner diameter dimension φA smaller than an outer diameter dimension φB of the shaft part 3 so as to perform a sealing function in close contact with the outer peripheral surface of the shaft part 3.

  Further, on the inner peripheral surface 4 a of the cancel plate 4, the metal part which is the material of the plate 4 is exposed as it is instead of the elastic body, and the cylindrical surface directly facing the outer peripheral surface of the shaft part 3. The eccentric regulation part 18 is provided, and the inner diameter dimension of the eccentric regulation part 18, that is, the inner diameter dimension φG of the cancel plate 4 is set slightly larger than the outer diameter dimension φB of the shaft part 3. Therefore, a very small radial gap is set between the eccentricity restricting portion 18 and the shaft portion 3.

  In the sealing structure having the above configuration, the sealing elastic body 17 is attached only to the axial end face 4b of the cancel plate 4 and not to the inner peripheral face 4a. Since the eccentric restricting portion 18 having a structure in which the metal portion, which is the material of the plate 4, directly faces the outer peripheral surface of the shaft portion 3 is provided on the peripheral surface 4 a, the eccentric restricting portion 18 is connected to the shaft portion 3. It functions as a radial stopper that suppresses the radial displacement of the cancel plate 4 by contacting the outer peripheral surface. Since the sealing elastic body 17 is not attached to the inner peripheral surface 4 a of the cancel plate 4, the inner diameter dimension of the eccentricity restricting portion 18, that is, the inner diameter dimension φG of the cancel plate 4 is extremely smaller than the outer diameter dimension φB of the shaft portion 3. The dimension difference h is set to a minimum. Therefore, it is possible to effectively suppress the cancel plate 4 from being eccentric with respect to the shaft portion 3 by the radial stopper function exhibited by the eccentricity restricting portion 18.

  Further, since the sealing elastic body 17 attached only to the axial end face 4b of the cancel plate 4 is not held by a rigid material on the back side (outer peripheral side), it can escape outward in the radial direction. In addition, when passing through the snap ring mounting groove 13 during mounting, it is possible to escape radially outward. Therefore, the ease of escaping makes it difficult for the sealing elastic body 17 to be caught in the mounting groove 13, so that the mounting property of the cancel plate 4 to the shaft portion 3 provided with the mounting groove 13 can be improved.

Second embodiment ...
FIG. 2 shows a cross section of the seal structure according to the second embodiment of the present invention. This second embodiment is an embodiment of the invention according to claims 1 and 2 of the present application.

  The seal structure according to this embodiment is a structure that seals the inner peripheral portion of the cancel plate 4 in the piston mechanism for an automatic transmission, and the cancel plate 4 disposed on the outer peripheral side of the shaft portion 3 and the shaft portion 3. And a snap ring 14 that is mounted in a mounting groove 13 provided on the outer peripheral surface and holds the cancel plate 4. The cancel plate 4 is attached to the inner peripheral end of the cancel plate 4 and is outer peripheral surface of the shaft portion 3. A sealing elastic body 17 is provided so as to be in close contact therewith.

  The sealing elastic body 17 is a fitting type sealing elastic body, and is not attached to the inner peripheral surface 4a of the cancel plate 4 but only to the axial end face 4b. That is, this sealing elastic body Reference numeral 17 denotes an end face attaching portion 17 b attached to the axial end face 4 b of the cancel plate 4. The end face adhering portion 17b is set to have an inner diameter dimension φD smaller than an outer diameter dimension φB of the shaft portion 3 so as to be fitted to the shaft portion 3 and to be in close contact with the outer peripheral surface of the shaft portion 3 to perform a sealing function. ing.

  Further, an unbonded portion 19 with respect to the cancel plate 4 is provided in the inner peripheral portion of the sealing elastic body 17 over a predetermined region I, and this unbonded portion 19 is attached as shown in FIG. It is configured to sometimes bend.

  Further, on the inner peripheral surface 4 a of the cancel plate 4, the metal part which is the material of the plate 4 is exposed as it is instead of the elastic body, and the cylindrical surface directly facing the outer peripheral surface of the shaft part 3. The eccentric regulation part 18 is provided, and the inner diameter dimension of the eccentric regulation part 18, that is, the inner diameter dimension φG of the cancel plate 4 is set slightly larger than the outer diameter dimension φB of the shaft part 3. Therefore, a very small radial gap is set between the eccentricity restricting portion 18 and the shaft portion 3.

  In the sealing structure having the above configuration, the sealing elastic body 17 is attached only to the axial end face 4b of the cancel plate 4 and not to the inner peripheral face 4a. Since the eccentric restricting portion 18 having a structure in which the metal portion, which is the material of the plate 4, directly faces the outer peripheral surface of the shaft portion 3 is provided on the peripheral surface 4 a, the eccentric restricting portion 18 is connected to the shaft portion 3. It functions as a radial stopper that suppresses the radial displacement of the cancel plate 4 by contacting the outer peripheral surface. Since the sealing elastic body 17 is not attached to the inner peripheral surface 4 a of the cancel plate 4, the inner diameter dimension of the eccentricity restricting portion 18, that is, the inner diameter dimension φG of the cancel plate 4 is extremely smaller than the outer diameter dimension φB of the shaft portion 3. The dimension difference h is set to a minimum. Therefore, it is possible to effectively suppress the cancel plate 4 from being eccentric with respect to the shaft portion 3 by the radial stopper function exhibited by the eccentricity restricting portion 18.

  Further, since the non-adhered portion 19 with respect to the cancel plate 4 is provided on the inner peripheral portion of the sealing elastic body 17 and is configured to bend at the time of mounting, the sealing elastic body 17 is easily escaped by the bending. Is not easily caught in the mounting groove 13. Therefore, the mounting property of the cancel plate 4 to the shaft portion 3 provided with the mounting groove 13 can be improved.

Third embodiment ...
FIG. 4 shows a cross section of the seal structure according to the third embodiment of the present invention. The third embodiment is an embodiment of the invention according to claims 1 and 3 of the present application.

  The seal structure according to this embodiment is a structure that seals the inner peripheral portion of the cancel plate 4 in the piston mechanism for an automatic transmission, and the cancel plate 4 disposed on the outer peripheral side of the shaft portion 3 and the shaft portion 3. And a snap ring 14 that is mounted in a mounting groove 13 provided on the outer peripheral surface and holds the cancel plate 4. The cancel plate 4 is attached to the inner peripheral end of the cancel plate 4 and is outer peripheral surface of the shaft portion 3. A sealing elastic body 17 is provided so as to be in close contact therewith.

  Further, an annular stepped portion 20 is provided on the outer peripheral surface of the shaft portion 3 above the mounting groove 13 and the upper portion has a larger diameter than the lower portion. The cancel plate 4 is mounted between the step portion 20.

  The sealing elastic body 17 is a lip type sealing elastic body, and is not attached to the inner peripheral surface 4a of the cancel plate 4 but only to the axial end face 4b. Is integrally provided with an end surface adhering portion 17b attached to the axial end surface 4b of the cancel plate 4 and a seal lip 17c formed integrally with the end surface adhering portion 17b and in close contact with the outer peripheral surface of the shaft portion 3. is doing. The seal lip 17c has an inner diameter dimension φA larger than the inner diameter dimension φG of the cancel plate 4 so as to improve the mounting property of the cancel plate 4, and the large-diameter side peripheral surface of the step portion 20 on the outer peripheral surface of the shaft portion 3 The inner diameter dimension φA is set to be smaller than the outer diameter dimension φJ of the large-diameter side peripheral surface 21 so as to perform a sealing function in close contact with 21.

  Further, on the inner peripheral surface 4 a of the cancel plate 4, the metal part which is the material of the plate 4 is exposed as it is instead of the elastic body, and the cylindrical surface directly facing the outer peripheral surface of the shaft part 3. The eccentric regulation part 18 is provided, and the inner diameter dimension of the eccentric regulation part 18, that is, the inner diameter dimension φG of the cancel plate 4 is set slightly larger than the outer diameter dimension φB of the shaft part 3. Therefore, a very small radial gap is set between the eccentricity restricting portion 18 and the shaft portion 3.

  In the sealing structure having the above configuration, the sealing elastic body 17 is attached only to the axial end face 4b of the cancel plate 4 and not to the inner peripheral face 4a. Since the eccentric restricting portion 18 having a structure in which the metal portion, which is the material of the plate 4, directly faces the outer peripheral surface of the shaft portion 3 is provided on the peripheral surface 4 a, the eccentric restricting portion 18 is connected to the shaft portion 3. It functions as a radial stopper that suppresses the radial displacement of the cancel plate 4 by contacting the outer peripheral surface. Since the sealing elastic body 17 is not attached to the inner peripheral surface 4 a of the cancel plate 4, the inner diameter dimension of the eccentricity restricting portion 18, that is, the inner diameter dimension φG of the cancel plate 4 is extremely smaller than the outer diameter dimension φB of the shaft portion 3. The dimension difference h is set to a minimum. Therefore, it is possible to effectively suppress the cancel plate 4 from being eccentric with respect to the shaft portion 3 by the radial stopper function exhibited by the eccentricity restricting portion 18.

  The cancel plate 4 is mounted between the snap ring 14 mounted in the mounting groove 13 provided on the outer peripheral surface of the shaft portion 3 and the stepped portion 20 provided on the outer peripheral surface of the shaft portion 3, and the sealing elastic body. 17 is configured so that its inner diameter dimension φA is set larger than the inner diameter dimension φG of the cancel plate 4 and is in close contact with the large-diameter side peripheral surface 21 of the stepped portion 20. There is no possibility of being caught in the mounting groove 13 without sliding on the peripheral surface of the shaft portion 3. Therefore, the mounting property of the cancel plate 4 to the shaft portion 3 provided with the mounting groove 13 can be improved.

Sectional drawing of the principal part of the seal structure which concerns on 1st Example of this invention. Sectional drawing of the principal part of the seal structure which concerns on 2nd Example of this invention. Cross-sectional view of the main part showing the state of occurrence of bending in the seal structure Sectional drawing of the principal part of the seal structure which concerns on 3rd Example of this invention. Explanatory drawing of piston mechanism Sectional view of the main part of the seal structure according to the conventional example Sectional drawing of the principal part of the seal structure which concerns on another prior art example

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Piston mechanism 2 Housing 3 Housing axial part 4 Cancel plate 5 Piston 6 Multi-plate clutch 7 Return spring 8, 10 Hydraulic chamber 9, 11 Oil supply port 12 Oil discharge port 13 Installation groove 14 Snap ring 15 Clutch press part 16, 17 Seal Elastic body 17a Inner peripheral surface adherence part 17b End face adherence part 17c Seal lip 18 Eccentricity restricting part 19 Unadhered part 20 Step part 21 Large diameter side peripheral surface

Claims (3)

This is a seal structure for the inner peripheral portion of the cancel plate (4) in the piston mechanism for an automatic transmission, and is provided on the cancel plate (4) arranged on the outer peripheral side of the shaft portion (3) and the shaft portion (3). A snap ring (14) that is mounted in the mounting groove (13) and holds the cancel plate (4), and is attached to the inner peripheral end of the cancel plate (4) to the shaft portion ( 3) In the sealing structure provided with the sealing elastic body (17) in close contact with
The elastic body for sealing (17) is attached only to the axial end surface (4b) at the inner peripheral end of the cancel plate (4), and to the inner peripheral surface (4a) of the cancel plate (4). Is provided with an eccentric regulating part (18) in which the metal part which is the material of the cancel plate (4) directly faces the shaft part (3). The seal structure according to claim 1,
The sealing elastic body (17) has a non-adhered part (19) with respect to the cancel plate (4), and is bent at the non-adhered part (19) when mounted. The seal structure according to claim 1,
The cancel plate (4) is mounted between the snap ring (14) mounted in the mounting groove (13) provided in the shaft portion (3) and the step portion (20) provided in the shaft portion (3).
The sealing elastic body (17) is set to have an inner diameter dimension larger than an inner diameter dimension of the cancel plate (4) and is in close contact with the large-diameter side peripheral surface (21) of the stepped portion (20). Seal structure.

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