JP6511349B2 - Exhaust fitting seal body - Google Patents

Description

  The present invention relates to an exhaust fitting seal body.

  As an exhaust pipe joint seal body, there is a gasket configured using expanded graphite and a metal mesh material made of a metal wire (see, for example, Patent Document 1). When the gasket described in Patent Document 1 is used in a joint for connecting two exhaust pipes, a pressure is applied to a flange provided on each of the two exhaust pipes while compressing and deforming a seal portion, It is comprised so that it may be pinched between flanges.

  However, in this gasket, since the seal portion is composed of expanded graphite and the metal mesh material covering the same from the outside, the flexibility in the seal portion can not be sufficiently secured, and the seal portion is made to correspond. When pressed against the flange, it has been difficult to make the amount of deformation of the seal (gasket crushing amount) along with the pressure contact substantially uniform in the circumferential direction of the gasket.

  Therefore, even if it looks as if the gasket has been installed properly after installation of the joint, relatively large variations occur in the amount of crushing of the gasket at the seal portion, whereby the sealing performance of the gasket is improved. There was a risk that it could not be fully demonstrated. Therefore, there is room for improvement from the viewpoint of enhancing the sealing performance of the gasket.

Japanese Patent Application No. 2014-151747

  This invention is made in view of such a situation, and aims at provision of the exhaust pipe joint seal object which can improve seal performance, securing sufficient intensity.

The invention according to claim 1 is
A tape-shaped expanded graphite is spirally wound and then compression-molded into an annular expanded graphite main body, and the main body is sealed to seal between the first exhaust pipe and the second exhaust pipe. An exhaust pipe joint seal body configured to be externally fitted to an end of the first exhaust pipe so as to be pressed by the first flange of the first exhaust pipe and the second flange of the second exhaust pipe. There,
A heat-resistant reinforcing member provided between expanded graphite layers formed to overlap in a radial direction of the main body by the tape-shaped expanded graphite,
The body is
A first seal portion provided on one axial end side of the main body and capable of being in pressure contact with the first flange;
It is provided on the other end side in the axial direction of the main body, and has a second seal portion that can be in pressure contact with the second flange,
The first seal portion and the second seal portion are made only of expanded graphite ,
The outermost expanded graphite layer has a bent portion in a cross section including the axial center of the main body between the first seal portion and the second seal portion at an axial midway portion of the main body.

  According to this configuration, when the exhaust pipe joint seal body is pinched by the first flange and the second flange while externally fitting the end fitting portion of the first exhaust pipe, the first seal portion and the second seal portion The first sealing portion and the second sealing portion are respectively provided on the first flange surface and the second flange surface by making the crushing amount (deformation amount) in each of the sealing portions substantially uniform. It makes it easy to press tightly over the entire circumference. Therefore, the sealing performance of the exhaust pipe joint seal body can be improved. Moreover, since the reinforcing member is provided between the expanded graphite layers in the main body, it is possible to secure sufficient strength for the exhaust pipe joint seal body.

The invention according to claim 2 is the exhaust pipe joint seal body according to claim 1,
The expanded graphite layer and the reinforcing member have a cross-sectional shape alternately overlapping in the radial direction of the main body.

  According to this configuration, it is possible to obtain a laminated structure of the expanded graphite layer and the reinforcing member over substantially the entire circumference of the exhaust pipe joint seal body. Therefore, the strength of the exhaust pipe joint seal can be further enhanced.

The invention according to claim 3 is the exhaust pipe joint seal body according to claim 1 or claim 2, another reinforcing member provided on the inner periphery of the main body so as to be exposed radially inward of the main body. It is further provided.

  According to this configuration, the exhaust pipe joint seal body and any one end portion of the first exhaust pipe and the second exhaust pipe can be easily attached, and the main body is broken at the time of the attachment operation. It is possible to suppress that a part of the expanded graphite is largely scraped off so that Therefore, while being able to improve the installation ease of the said exhaust pipe joint seal, the fall of the sealing performance of the said exhaust pipe joint seal can be prevented.

The invention according to claim 4 is the exhaust pipe joint seal body according to any one of claims 1 to 3,
The first seal portion has a tapered seal surface for pressing against a portion of the first flange surface of the first flange;
The second seal portion has a tapered seal surface for pressing against a portion of the second flange surface of the second flange;
The first seal portion and the second seal portion are formed in a symmetrical shape with an outer peripheral portion provided between the first seal portion and the second seal portion in the main body. is there.

  According to this configuration, the first seal portion of the exhaust pipe joint seal body is reliably provided on a part of the first flange surface of the first flange in accordance with the respective shapes of the first flange and the second flange. While being able to press hard, the 2nd seal part of the exhaust joint seal body can be firmly pushed firmly to a part of 2nd flange side of the 2nd flange.

  Therefore, it can prevent that the sealing performance by the said exhaust pipe joint seal body falls. In addition, after mounting the exhaust pipe joint seal body, sealing performance can be reliably exhibited regardless of the direction of the exhaust pipe joint seal body. Therefore, when the mounting work of the exhaust pipe joint seal body is performed, the direction of the exhaust pipe joint sealing body does not have to be taken into consideration, so the mounting easiness can be further enhanced.

  According to the present invention, it is possible to provide an exhaust pipe joint seal body capable of improving seal performance while securing sufficient strength.

It is a schematic sectional drawing of the seal structure by the exhaust pipe joint seal body which concerns on one Embodiment of this invention. It is a front view of the exhaust pipe joint seal body of FIG. It is a top view of the exhaust pipe joint seal object of FIG. It is II arrow sectional drawing of FIG. FIG. 5 is a partially enlarged view of FIG. 4; It is a partially expanded schematic cross section of the exhaust pipe joint seal body of FIG. It is a schematic sectional drawing which shows the state in the middle of mounting | wearing with the exhaust pipe coupling seal body of FIG. (A) is a schematic sectional drawing which shows the initial state of the 2nd seal part in the exhaust pipe joint seal body of FIG. 1, (b) is a schematic sectional drawing which shows the state after compressive deformation of this 2nd seal part . It is a partially enlarged view of FIG. (A) is a schematic sectional drawing which shows the initial state of the projection part in the exhaust pipe joint seal body of FIG. 1, (b) is a schematic which shows the state which the end of a 1st exhaust pipe acts with respect to this projection part FIG. It is a schematic cross section seen from the arrow II direction of FIG. It is a figure which shows the flow of the manufacturing method of the exhaust pipe coupling seal body of FIG. It is a schematic diagram which shows the state of the composite body formation process in the manufacturing method of the exhaust pipe joint seal body of FIG. FIG. 14 is a view including a partially enlarged view of a complex obtained by the complex formation step of FIG. 13; It is a figure which shows the state of the cylindrical body formation process in the manufacturing method of the exhaust pipe joint sealing body of FIG. It is a figure which shows the state of the compression molding process in the manufacturing method of the exhaust pipe joint seal body of FIG. FIG. 15 is a cross-sectional view of the composite of FIG. It is a schematic diagram which shows the state of the composite body formation process of another embodiment in the manufacturing method of the exhaust pipe joint seal body of FIG. It is sectional drawing of the composite obtained by the composite formation process of another embodiment in the manufacturing method of the exhaust pipe joint seal body of FIG.

  Embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a schematic side cross-sectional view of a seal structure with an exhaust pipe joint seal body according to an embodiment of the present invention. Hereinafter, the gasket 1 will be described as an example of the exhaust pipe joint seal body.

  As shown in FIG. 1, the gasket 1 is used for a joint 2 in an exhaust pipe of a car or the like. In the present embodiment, the exhaust pipe has a first exhaust pipe 3 and a second exhaust pipe 4 which can be joined to each other through the joint 2. The first exhaust pipe 3 and the second exhaust pipe 4 are each formed of a cylindrical steel pipe, and are arranged such that their joint portions are coaxially located at the time of joining.

  The joint 2 realizes a seal structure by the gasket 1 and the second end of the first exhaust pipe 3 facing the axial direction one end (hereinafter, simply referred to as an end) 7 at a predetermined interval. It is configured to be able to join an axial end (hereinafter simply referred to as an end) 8 of the exhaust pipe 4. The joint 2 includes a first flange 11, a second flange 12, and a pressure welding mechanism 13 in addition to the gasket 1.

  The first flange 11 is attached to the end portion 7 of the first exhaust pipe 3 so as to surround it from the outside. The first flange 11 has an annular shape, and is configured using a sheet metal. The first flange 11 protrudes radially outward from the outer peripheral surface of the end portion 7 of the first exhaust pipe 3 so that the first flange surface 15 can be directed to the second exhaust pipe 4 side. ing.

  In the present embodiment, the first flange 11 has a first cylindrical portion 17, a first tapered portion 18 and a first contact portion 19. The first tubular portion 17 is externally fitted and fixed to the end portion 7 of the first exhaust pipe 3. The first tapered portion 18 extends radially outward from the first cylindrical portion 17. The first contact portion 19 extends radially outward from the first tapered portion 18.

  Specifically, the first cylindrical portion 17 is disposed at a position spaced apart from the one end face 21 of the first exhaust pipe 3 by a predetermined distance on the other axial end side of the first exhaust pipe 3. Thus, the end portion 7 of the first exhaust pipe 3 includes the extending portion 22 for externally fitting the gasket 1 between the fixed position with the first cylindrical portion 17 and the one end surface 21. It is supposed to be.

  The first tapered portion 18 is disposed on one end side in the axial direction of the first cylindrical portion 17 and gradually expands in diameter from the first cylindrical portion 17 to one end side in the axial direction of the first exhaust pipe 3 It is formed in a tapered cylindrical shape. The first tapered portion 18 has a tapered inner peripheral surface (concave curved surface) which forms a part of the first flange surface 15. The inner peripheral surface includes a first pressure contact surface 23 that can be in pressure contact with the gasket 1.

  The first contact portion 19 is disposed radially outward of the first tapered portion 18 and is connected to the radially outermost portion (axial one end portion) of the first tapered portion 18. The first contact portion 19 has a substantially flat surface which is a part of the first flange surface 15. This surface includes a first abutment surface 24 that can abut on the second flange 12.

  The second flange 12 is attached to the end 8 of the second exhaust pipe 4 so as to surround it from the outside. The second flange 12 has an annular shape, and is configured using a sheet metal. The second flange 12 protrudes radially outward from the outer peripheral surface of the end portion 8 of the second exhaust pipe 4 so that the second flange surface 25 can be directed to the first exhaust pipe 3 side. ing.

  In the present embodiment, the second flange 12 has a second cylindrical portion 27, a second tapered portion 28, and the second contact portion 29. The second cylindrical portion 27 is externally fitted and fixed to the end 8 of the second exhaust pipe 4. The second tapered portion 28 extends radially outward from the second tubular portion 27. The second contact portion 29 extends radially outward from the second tapered portion 28.

  Specifically, the second cylindrical portion 27 is disposed such that one axial end thereof is closer to the axial one end 7 of the first exhaust pipe 3 than the one end face 31 of the second exhaust pipe 4. ing. That is, one axial end portion of the second cylindrical portion 27 is positioned such that one end surface 31 of the second exhaust pipe 4 is positioned radially inward of the second cylindrical portion 27. Fixed to the end 8 of the

  The second tapered portion 28 is disposed on one axial end side of the second cylindrical portion 27 and gradually expands in diameter from the second cylindrical portion 27 toward one axial end side of the second exhaust pipe 4. It is formed in a tapered cylindrical shape. The second tapered portion 28 has a tapered inner peripheral surface (concave curved surface) which forms a part of the second flange surface 25. The inner peripheral surface includes a second pressure contact surface 33 that can be in pressure contact with the gasket 1.

  The second contact portion 29 is disposed radially outward of the second tapered portion 28 and is connected to the radially outermost portion (one end portion in the axial direction) of the second tapered portion 28. The second contact portion 29 has a substantially flat surface which is a part of the second flange surface 25. This surface includes a second contact surface 34 that can contact the first flange 11 (the first contact surface 24).

  As shown in FIG. 1, when the second contact portion 29 contacts the first contact surface 24 of the first contact portion 19 at the second contact surface 34, the second tapered portion 28 It faces the first tapered portion 18 at a predetermined distance. Thus, an accommodation space capable of accommodating the gasket 1 in a state of being externally fitted to the extension portion 22 can be formed between the first taper portion 18 and the second taper portion 28. .

  The gasket 1 includes a gasket body 41 made of expanded graphite. The gasket main body 41 is annularly formed by compression molding after the tape-like expanded graphite is wound in a spiral shape. In the present embodiment, the gasket 1 has an annular shape based on the gasket main body 41, and is formed so as to be able to be closely fitted to the end portion 7 (the extension portion 22) of the first exhaust pipe 3 It is done.

  The gasket 1 is tightly attached to the end 7 of the first exhaust pipe 3 in order to seal between the end 7 of the first exhaust pipe 3 and the end 8 of the second exhaust pipe 4. Between the two flanges 11 and 12 so that the gasket body 41 can be pressed between the first tapered portion 18 of the first flange 11 and the second tapered portion 28 of the second flange 12 after fitting. It is configured to be interposed.

  The pressure welding mechanism 13 is interposed between the first flange 11 and the second flange 12 in a state where the gasket 1 is closely fitted to the end 7 of the first exhaust pipe 3. The first flange 11 and the second flange 12 can be fastened so that the first pressing surface 23 of the first tapered portion 18 and the second pressing surface 33 of the second tapered portion 28 sandwich the gasket 1. It is configured.

  In the present embodiment, the pressure welding mechanism 13 has a bolt 45 and a nut 46. The bolt 45 is configured to be able to pass through the first contact portion 19 of the first flange 11 and the second contact portion 29 of the second flange 12 that are in contact with each other. The nut 46 is configured to be able to be tightened on the bolt 45.

  Thus, when the gasket 1 is interposed between the first flange 11 and the second flange 12, the bolt 45 is inserted through the flanges 11 and 12 so that the bolt 45 and the nut 46 are inserted. By tightening, the first pressing surface 23 and the second pressing surface 33 can be press-contacted so that the gasket 1 and a part thereof are compressed and deformed.

  Next, the gasket 1 will be described in detail.

  FIG. 2 shows a front view of the gasket 1. The top view of the said gasket 1 is shown in FIG. FIG. 4 shows a simplified sectional view taken along the line I-I in FIG. FIG. 5 shows a partially enlarged view of FIG. FIG. 6 shows a partially enlarged schematic cross-sectional view of the gasket 1.

  As shown in FIGS. 1, 2, 3, 4, 5 and 6, the gasket 1 is configured using expanded graphite 51 and a metal mesh material 52, and includes the gasket body 41. ing. As for the gasket 1, the expanded graphite 51 and the metal mesh material 52 are specifically shown in FIG. 6 for the sake of convenience, and are omitted in the other drawings.

  In the gasket 1, the gasket main body 41 is an annular ring made of expanded graphite, which is formed by compression-molding a tape-shaped expanded graphite after being wound in a spiral shape. Therefore, the gasket 1 has a cross-sectional shape in which a plurality of expanded graphite layers 51a made of the expanded graphite 51 are stacked in the radial direction of the gasket main body 41, as shown in FIG.

  In addition, the metal mesh material 52 is provided between the expanded graphite layers 51 a formed so as to overlap in the radial direction of the gasket body 41. The metal mesh material 52 is an example of a heat-resistant reinforcing member, and in the present embodiment, the metal mesh material 52 is disposed in the axial midway portion of the gasket main body 41 in a state of being in contact with the expanded graphite layer 51a.

  The metal mesh material 52 has a predetermined width in the axial direction of the gasket body 41, and is in contact with the outermost expanded graphite layer 51a of the expanded graphite layer 51a located on the radially outer side of the gasket body 41. The widthwise end portions 52a and 52b are provided so as to be continuous to the inside of the later-described first seal portion 53 and second seal portion 54 applied to the outermost expanded graphite layer 51a.

  The metal mesh material 52 is surrounded by the expanded graphite layer 51 a so as not to be exposed to the outside of the gasket main body 41 (radial outer side and axial outer side of the gasket main body 41). Although the metal mesh material 52 extends seamlessly along the expanded graphite layer 51a in the circumferential direction of the gasket body 41, the metal mesh material 52 may be provided only in a partial region between the expanded graphite layer 51a. Good.

  The metal mesh material 52 is formed into a tape shape so as to have a gap by knitting the metal wire in a mesh shape by a predetermined knitting method (knit knitting in this embodiment) such as knit knitting or bag knitting. A flexible member. As the metal wire, a metal wire having a predetermined wire diameter (thickness), for example, a stainless steel wire having a diameter of about 0.1 to 0.3 mm (preferably, 0.15 mm) may be employed.

  Here, although the metal mesh material 52 is adopted as the reinforcing member, for example, a tubular metal mesh material and a tape-like expansion surrounded by the metal mesh material instead of the metal mesh material 52 are used. You may employ | adopt the member which consists of graphite.

  Further, the gasket body 41 has the first seal portion 53 and the second seal portion 54. The first seal portion 53 can be brought into pressure contact with a portion of the first flange surface 15 of the first flange 11 (the first pressing surface 23) while being compressed and deformed. The second seal portion 54 can be in pressure contact with a portion (the second pressure contact surface 33) of the second flange surface 25 of the second flange 12 while being compressed and deformed.

  In the present embodiment, the gasket main body 41 has a cylindrical shape which is tapered on one end side and the other end side in the axial direction. That is, in the gasket body 41, a tapered first outer peripheral tapered portion whose diameter is gradually reduced toward the axial direction end from the axial direction middle portion is provided on the axial direction one end side, and the axial direction halfway portion to the axial other end side A tapered second outer peripheral tapered portion whose diameter gradually decreases toward the end is provided on the other end side in the axial direction.

  The first seal portion 53 is provided on the other end side in the axial direction of the gasket main body 41 and is disposed on the radially outer side of the gasket main body 41. Specifically, the first seal portion 53 is provided in the second outer peripheral tapered portion of the gasket body 41 and in the vicinity thereof. Thus, the first seal portion 53 is configured to have a seal surface which is tapered toward the other axial end side.

  The first seal portion 53 has a first tapered portion 53a, a second tapered portion 53b and a curved portion 53c, and the first tapered portion 53a, the second tapered portion 53b and the curved portion 53c are respectively compressed and deformed. At the same time, the first pressure contact surface 23 is configured to be press-contactable. The second tapered portion 53b has a taper angle different from that of the first tapered portion 53a.

  Specifically, the second tapered portion 53b is disposed between the first tapered portion 53a and the curved portion 53c, and is formed to have a larger taper angle than the first tapered portion 53a. The curved portion 53c is disposed between the second tapered portion 53b and the other axial end 55 of the gasket main body 41, and is formed in a curved shape (R shape) which is convex outward.

  The second seal portion 54 is provided on one end side in the axial direction of the gasket main body 41 and is disposed on the radially outer side of the gasket main body 41. Specifically, the second seal portion 54 is provided in the first outer peripheral tapered portion of the gasket main body 41 and in the vicinity thereof. Thus, the second seal portion 54 is configured to include a seal surface which is tapered toward one end side in the axial direction.

  The second seal portion 54 has a first tapered portion 54a, a second tapered portion 54b and a curved portion 54c, and the first tapered portion 54a, the second tapered portion 54b and the curved portion 54c are respectively compressed and deformed. At the same time, the second pressure contact surface 33 is configured to be press-contactable. The second tapered portion 54b has a taper angle different from that of the first tapered portion 54a.

  Specifically, the second tapered portion 54b is disposed between the first tapered portion 54a and the curved portion 54c, and is formed to have a larger taper angle than the first tapered portion 54a. The curved portion 54 c is disposed between the second tapered portion 54 b and the one axial end 56 of the gasket body 41, and is formed in a curved shape (R shape) which is convex toward the outside.

  Here, the first seal portion 53 and the second seal portion 54 are both present in the gasket main body 41, and are formed only of expanded graphite. Therefore, each of the first seal portion 53 and the second seal portion 54 is compressed by a predetermined amount along with the above-described pressure contact without being influenced by the metal mesh material 52 provided inside the gasket main body 41. It has become deformable.

  Therefore, the first seal portion 53 and the second seal portion 54 each have the first flange 11 after the gasket 1 is externally fitted to the end portion 7 of the first exhaust pipe 3 (see FIG. 7). When pressed against the first pressing surface 23 and the second pressing surface 33 of the second flange 12 (see FIG. 1), the gasket can be compressed and deformed so that the amount of crushing of the gasket becomes substantially uniform in the circumferential direction. ing.

  When sandwiching the gasket 1 by the first flange 11 and the second flange 12 while externally fitting the gasket 1 to the end portion 7 of the first exhaust pipe 3 for installation of the joint 2 with such a configuration, The first seal portion 53 and the second seal portion 54 can be easily pressed tightly against the first pressing surface 23 and the second pressing surface 33 over substantially the entire circumferential direction of the gasket body 41, respectively.

  Therefore, the sealing performance of the gasket 1 can be improved. Moreover, since the metal mesh material 52 is provided between the expanded graphite layer 51 a in the gasket main body 41, it is possible to secure sufficient strength of the gasket 1. In addition, with respect to the gasket 1, it is possible to obtain flexibility capable of enhancing the ease of attachment (insertability) to the first exhaust pipe 3.

  In the present embodiment, as shown in FIG. 6, the gasket 1 has a cross-sectional shape in which the expanded graphite layer 51 a and the metal mesh material 52 alternately overlap in the radial direction of the gasket body 41. ing. That is, in a cross-sectional view including the axial center of the gasket body 41, the metal mesh material 52 is provided anywhere between the adjacent expanded graphite layers 51a.

  With such a configuration, a laminated structure of the expanded graphite layer 51 a and the metal mesh material 52 can be obtained over substantially the entire circumference of the gasket 1 in the circumferential direction. Therefore, the strength of the gasket 1 can be further enhanced. Here, in consideration of the flexibility of the gasket 1, the thickness of each of the expanded graphite layer 51a and the metal mesh material 52 is appropriately set.

  Further, in the present embodiment, as shown in FIG. 6, the gasket 1 further includes another metal mesh material 57. The other metal mesh material 57 is provided on the inner periphery of the gasket body 41 so as to be exposed to the inside in the radial direction of the gasket body 41, and is positioned on the innermost side in the radial direction among the plurality of expanded graphite layers 51a. It is disposed adjacent to the expanded graphite layer 51a.

  The other metal mesh material 57 has the same structure as that of the metal mesh material 52 and is integrally formed with it. The other metal mesh material 57 is covered with the expanded graphite 51 so as not to be exposed to the outside in the axial direction of the gasket body 41. The other metal mesh material 57 is formed to be in contact with the end 7 of the first exhaust pipe 3 when the gasket 1 is externally fitted.

  With such a configuration, the gasket 1 and the end portion 7 of the first exhaust pipe 3 can be easily attached, and the expansive graphite 51 is formed so that the gasket main body 41 is broken during the attachment operation. It can suppress that a part is scraped off largely. Therefore, while being able to improve the installation ease of the said gasket 1, the fall of the sealing performance of the said gasket 1 can be prevented.

  Further, in the present embodiment, as shown in FIGS. 2, 3, 4 and 5, an outer peripheral portion 58 is formed between the first seal portion 53 and the second seal portion 54 in the gasket main body 41. Is provided. The outer peripheral portion 58 is a portion formed so as to be exposed to the outside by the expanded graphite layer 51a positioned on the outermost radial direction in the expanded graphite layer 51a, and includes a projecting portion 58a protruding outward in the radial direction. There is.

  Then, as described above, the first seal portion 53 and the second seal portion 54 are respectively formed on a portion of the first flange surface 15 of the first flange 11 and a portion of the second flange surface 25 of the second flange 12. A symmetrical shape having an abuttable tapered seal surface across the outer peripheral portion 58 (a shape symmetrical to a plane passing through the axial center of the gasket body 41 and passing through the axial center) Is formed.

  With this configuration, the first seal portion 53 of the gasket 1 is firmly pressed firmly against the first pressing surface 23 of the first flange 11 in accordance with the shapes of the first flange 11 and the second flange 12. In addition, the second seal portion 54 of the gasket 1 can be surely and strongly pressed against the second pressure contact surface 33 of the second flange 12.

  Therefore, the sealing performance of the gasket 1 can be prevented from being degraded. Moreover, after the mounting of the gasket 1, the sealing performance can be reliably exhibited regardless of the direction of the gasket 1. Therefore, when the mounting work of the gasket 1 is performed, the direction of the gasket 1 does not have to be taken into consideration, so the mounting ease can be further enhanced.

  Further, as shown in FIG. 6, the gasket 1 is provided with a bent portion 51 b bent at an acute angle in the radial direction of the gasket main body 41 in the gasket main body 41. In the present embodiment, the bent portion 51 b is configured by using the outermost expanded graphite layer 51 a of the expanded graphite layer 51 a, and is provided at a midway in the axial direction of the gasket main body 41.

  The bent portion 51 b is formed by bending the outermost expanded graphite layer 51 a in a V shape in a cross-sectional view orthogonal to the axial center of the gasket main body 41. Thus, the bent portion 51 b is provided so as to be sandwiched between the first seal portion 53 and the second seal portion 54. The metal mesh material 52 is provided with a bending portion 52c along the bending portion 51b.

  With this configuration, when the gasket 1 is pressed between the first flange 11 and the second flange 12, the repulsive force due to the bending of the bent portion 51b (further, the bent portion 52c) is used to The contact surface pressure when the first seal portion 53 contacts the first taper portion 18 and the contact surface pressure when the second seal portion 54 contacts the second taper portion 28 can be increased. It becomes. Therefore, high sealing performance can be ensured for the first seal portion 53 and the second seal portion 54.

  Further, as shown in FIG. 1, FIG. 3, FIG. 4, FIG. 5 and FIG. 9, the gasket 1 has a first recess 61. The first concave portion 61 is located radially inward of the second seal portion 54 in order to receive a portion of the gasket main body 41 made of the expanded graphite 51 which moves according to compression deformation accompanying pressure contact of the second seal portion 54. It is provided in the inner peripheral edge part of the axial direction one end side of the said gasket main body 41 so that it may be located.

  The first concave portion 61 has a substantially constant radial width and axial width, and is formed to extend in an annular shape (annular shape) all around the inner circumferential direction of the gasket main body 41. The expanded graphite which forms the second seal portion 54 so that the displacement of the inner surface of the first concave portion 61 is generated along with the compressive deformation of the second seal portion 54 (see FIGS. 8A and 8B). It is formed of expanded graphite 51 arranged continuously with 51.

  The radial width of the first recess 61 is appropriately set with respect to the radial width of the gasket body 41 so that the sealing performance of the second seal portion 54 is not impaired. Further, the axial width of the first recess 61 is appropriately set with respect to the axial width of the gasket main body 41 so that the strength of the gasket main body 41 is not largely deteriorated.

  On the inner surface of the first recess 61, a flat portion 61a included in a plane substantially orthogonal to the axial center of the gasket main body 41, and an inclined portion 61b located radially outward of the flat portion 61a and at one end in the axial direction Is equipped. The inclined portion 61b is located closest to the second seal portion 54 in the first concave portion 61, and is formed so as to gradually increase in diameter from the flat portion 61a toward one end in the axial direction.

  When the gasket main body 41 is pinched between the first flange 11 and the second flange 12 in the state where the gasket 1 is externally fitted to the end portion 7 of the first exhaust pipe 3 by such a configuration. As shown in FIG. 8, when the second seal portion 54 is compressed and deformed from the initial shape by pressure contact with the second flange 12, a portion of the gasket main body 41 moving radially inward is It can be accommodated in the recess 61.

  Therefore, even when deformation of the second seal portion 54 occurs, the inner peripheral edge portion of the gasket main body 41 extends along the end portion 7 of the first exhaust pipe 3 more axially than the first exhaust pipe 3. It can not be pushed upwards in the direction. Therefore, regardless of the fixing position of the gasket 1 in the first exhaust pipe 3, the gasket main body 41 can be prevented from jumping beyond the end face 21.

  Therefore, a sufficient amount of the expanded graphite 51 forming the second seal portion 54 is secured in accordance with the shape of the second flange 12 so that the sealing performance of the second seal portion 54 is not impaired. It becomes possible. As a result, the sealing performance of the second seal portion 54 and hence the sealing performance of the gasket 1 can be sufficiently and surely exhibited.

  Furthermore, as shown in FIGS. 1, 4 and 5, the gasket 1 is provided with an annular second recess 62. The diameter of the first seal portion 53 is to receive the other part of the gasket main body 41 made of the expanded graphite 51 which moves according to the compression deformation accompanying the pressure contact of the first seal portion 53. It is provided in the inner peripheral edge part of the axial direction other end side of the said gasket main body 41 so that it may be located inside direction.

  Specifically, the second recess 62 is formed symmetrically with the first recess 61 and the outer peripheral portion 58 of the gasket main body 41 interposed therebetween. Thus, on the inner surface of the second recess 62, the flat portion 62a included in a plane substantially orthogonal to the axial center of the gasket main body 41, and the inclined portion located on the radially outer side and the other axial end side of the flat portion 62a. 62b and are provided.

  Even when the gasket 1 is externally fitted to the end portion 7 of the first exhaust pipe 3 in such a state that the direction of the gasket 1 is reversed, the first concave portion 61 is substituted for the first concave portion 61. The second recess 62 can be used to obtain the same effect as described above. Therefore, when the mounting work of the gasket 1 is performed, the direction of the gasket 1 does not have to be taken into consideration, so that the mounting ease can be enhanced.

  Further, as shown in FIG. 3, FIG. 4, FIG. 5 and FIG. 9, the gasket 1 is provided with a projection 71. The protrusion 71 is provided in a part in the axial direction so as to protrude radially inward on the inner periphery of the gasket main body 41. The projection 71 is configured to be in pressure contact while scraping off a part of the end 7 entering into the gasket main body 41 when the first exhaust pipe 3 is externally fitted to the end 7. .

  In the present embodiment, a plurality (three) of the protrusions 71 are provided. The plurality of projections 71 are arranged at predetermined intervals in the circumferential direction of the gasket 1. Specifically, the plurality of protrusions 71 are arranged substantially equally at intervals of about 120 degrees. In addition, the plurality of protrusions 71 are respectively disposed on the inner circumferential surface of the gasket 1 in the middle in the axial direction.

  Each of the protrusions 71 is mainly made of expanded graphite, and is integrally formed with the expanded graphite layer 51a positioned inward in the radial direction among the plurality of expanded graphite layers 51a. Although the surface of each protrusion 71 has a portion where the metal wire constituting the other metal mesh material 57 is polymerized, the exposure of each protrusion 71 is not greatly inhibited by this.

  Each of the protrusions 71 does not impair the insertability of the end portion 7 of the first exhaust pipe 3 which is made to enter into the gasket 1 when externally fitted to the end portion 7 of the first exhaust pipe 3. When the protrusions 71 hit the end 7 of the first exhaust pipe 3 during insertion, the gasket 1 is projected in a predetermined direction in the radial direction so that it can be pressed against the end 7 when the end is cut off. Have a quantity.

  With such a configuration, as shown in FIGS. 10A and 10B, in order to externally fit the gasket 1 to the end 7 of the first exhaust pipe 3, the end 7 is inserted into the gasket 1. At the time of entry, each of the protrusions 71 can be brought into pressure contact with the end 7 of the first exhaust pipe 3 whose part has been scraped off, and the gasket 1 can be retained and held against this end 7. Therefore, the mounting ease of the gasket 1 can be enhanced.

  Further, in the present embodiment, since the plurality of protrusions 71 are provided on the inner peripheral surface of the gasket 1, each of the plurality of protrusions 71 and the end portion 7 of the first exhaust pipe 3 are provided. The pressure contact can be performed well, and the retaining effect of the gasket 1 on the end portion 7 of the first exhaust pipe 3 can be enhanced.

  In the gasket 1, three projections 71 are provided in the present embodiment, but any number may be considered in consideration of the insertability and the like of the end portion 7 of the first exhaust pipe 3 into the gasket 1. You may provide only.

  Further, in the present embodiment, each of the protrusions 71 has a top 71a located at a midway in the axial direction of the gasket main body 41, and the other axial end of the top 71a (the end of the first exhaust pipe 3 And the first inclined portion 71b located on the approach side of (7). The first inclined portion 71b is formed in an inclined shape in which the amount of projection of each protrusion 71 gradually decreases from the top 71a toward the other end in the axial direction.

  That is, each of the protrusions 71 is formed in a trapezoidal shape (or an arc shape) which protrudes inward in the radial direction of the gasket main body 41 in a sectional view including the axial center of the gasket main body 41. Thus, when the end portion 7 of the first exhaust pipe 3 enters into the gasket 1, the end portion 7 of the first exhaust pipe 3 is hit after hitting the first inclined portion 71 b of the projection 71. It becomes possible to guide smoothly in the direction of movement.

  Further, in the present embodiment, as shown in FIG. 5, each of the protrusions 71 is located on the opposite side to the first inclined portion 71 b with respect to the top 71 a in the axial direction of the gasket main body 41. And an inclined portion 71c. The second inclined portion 71c is formed in an inclined shape in which the amount of projection of each of the protrusions 71 gradually decreases from the top portion 71a toward the one axial end side (opposite side).

  Specifically, the two inclined portions 71 c are formed symmetrically with the first inclined portion 71 b and the top portion 71 a interposed therebetween. Thereby, even if the end 7 of the first exhaust pipe 3 is inserted from the opposite direction into the gasket 1 for the outer fitting, the first inclined portion 71b is replaced with the first inclined portion 71b. It becomes possible to smoothly approach the end of the first exhaust pipe using the two inclined portion 71c.

  Further, in the present embodiment, as shown in FIG. 11, the metal mesh material 52 is made of a knitted fabric in which a metal wire 78 such as a stainless steel wire is knitted by knit knitting. In more detail, the metal mesh material 52 is formed of a weft-knitted fabric in which the metal wire 78 is supplied from the winding direction to continuously bind the loop 52d in the vertical direction (longitudinal direction).

  The metal mesh material 52 is provided on the gasket main body 41 so that the loop 52d bulges generally in the axial direction of the gasket 1 while having a bulging shape that is convex in the circumferential direction. There is. Thereby, the metal mesh material 52 can apply an elastic force in the axial direction to the gasket main body 41 (the gasket 1).

  Therefore, when the gasket 1 is pinched between the first tapered portion 18 of the first flange 11 and the second tapered portion 28 of the second flange 12 disposed on both sides in the axial direction of the gasket body 41, The contact surface pressure at each of the first seal portion 53 and the second seal portion 54 can be maintained, that is, the relaxation of stress can be suppressed by utilizing the repulsive force of elasticity of the loop 52 d.

  Next, a method for manufacturing the gasket 1 will be described.

  FIG. 12 shows a flow of a method of manufacturing the gasket 1. FIG. 13 shows the state of the composite formation step in the method of manufacturing the gasket 1. FIG. 14 shows a view including a partially enlarged view of a complex 83 obtained by the complex formation step. The state of the cylindrical body formation process in the manufacturing method of the said gasket 1 is shown in FIG. FIG. 16 shows the state of the compression molding process in the method of manufacturing the gasket 1.

  As shown in FIG. 12, in the method of manufacturing the gasket 1, a material preparation step (first step) S1, a complex formation step (second step) S2, and a cylindrical body formation step (third step) S3. And a compression molding step (fourth step) S4. Then, the material preparation step S1, the composite formation step S2, the cylindrical body formation step S3 and the compression molding step S4 can be performed in this order.

  In the material preparation step S1, a tape-like expanded graphite 81, which is a material having heat resistance and flexibility, and a tape-like reinforcing member having a smaller tape area than the tape-like expanded graphite 81 are prepared ( See Figure 13). The tape-like reinforcing member is a tape-like metal mesh material 82 here. The tape-shaped expanded graphite 81 forms the gasket body 41, and the tape-shaped reinforcing member forms the reinforcing member of the gasket 1.

  In the present embodiment, the tape-shaped expanded graphite 81 and the tape-shaped metal mesh material 82 are each formed in a rectangular shape. As shown in FIGS. 13 and 14, the tape-shaped metal mesh material 82 has a longitudinal length substantially equal to the longitudinal length of the tape-shaped expanded graphite, and the tape-shaped expanded graphite It has a width direction width smaller than the width direction width 81.

  For example, the tape-like expanded graphite 81 is formed to have a thickness of about 0.2 to 0.3 mm. The metal mesh material 82 in the form of a tape is a knit formed by knitting metal wires 84 having a diameter of about 0.15 mm, and is formed to have a thickness of about 0.2 to 0.3 mm.

  In the composite formation step S2, as shown in FIGS. 13 and 14, in order to form the composite 83, the outer peripheral edge portion of the tape-shaped metal mesh material 82 is outside the expanded graphite 81 in the tape shape. The tape-shaped expanded graphite 81 and the tape-shaped metal mesh material 82 overlap each other in a state where the both 81 and 82 are opposed to each other so as to be positioned inside the peripheral portion.

  The expanded graphite 81 in the form of a tape is provided such that the outer peripheral edge protrudes outward beyond the outer peripheral edge of the tape-like metal mesh material 82 on each of both sides in the short direction. In the present embodiment, the metal mesh material 82 in the form of a tape is extended along the longitudinal direction of the expanded graphite 81 in the form of a tape, and disposed at the approximate center of the expanded graphite 81 in the form of a tape. ing.

  That is, as shown in FIG. 14, in the case where the widthwise width W1 of the tape-shaped expanded graphite 81 and the widthwise width W2 of the tape-shaped metal mesh material 82 are used, in the composite 83, the tape The expanded graphite 81 in the form of a loop is provided with portions which do not polymerize on the tape-like metal mesh material 82 and the predetermined width direction width W3 · W4 on both sides in the width direction.

  In the cylindrical body forming step S3, as shown in FIG. 15, the tape-like members overlapping each other to form a spirally wound cylindrical body 85 in a multi-rolling state in which the short direction of the composite 83 is the axial direction. The composite 83 is spirally wound so that the tape-like metal mesh material 82 of the expanded graphite 81 and the tape-like metal mesh material 82 is positioned inside.

  In the compression molding step S4, in order to obtain the gasket 1, the spirally wound cylindrical body 85 is compression molded. For example, as shown in FIG. 16, a fixed mold 86 corresponding to the shape of the gasket 1 and a movable mold 87 movable back and forth with respect to the fixed mold 86 are prepared, and the fixed mold 86 and the movable mold 87 are used. The helical cylinder 85 is compression molded.

  Specifically, first, the spirally wound cylindrical body 85 is externally fitted to the inner fixed mold 88 in the fixed mold 86 and installed between the inner fixed mold 88 and the outer fixed mold 89. Next, the movable mold 87 is moved in the direction of the arrow 90 and pushed between the inner fixed mold 88 and the outer fixed mold 89. Thus, the spirally wound cylindrical body 85 is compression molded.

  By the completion of the compression molding step S4, the gasket 1 configured using the expanded graphite 51, the metal mesh material 52, and the other metal mesh material 57 can be obtained. In the present embodiment, the compression molding step S4 appropriately performs the compression molding of the spirally cylindrical body 85 so as to form the first recess 61, the second recess 62, and the protrusion 71. It has become.

  With such a configuration, the first seal portion can be tightly pressed against the first flange 11 (the first pressing surface 23) of the first exhaust pipe 3 by using only the expanded graphite 51 in the gasket 1 53 and the second seal portion 54 that can be tightly pressed against the second flange 12 (the second pressure contact surface 323) of the second exhaust pipe 4; Thus, the gasket 1 with improved sealing performance can be obtained simply and reliably.

  And since it becomes easy to expose relatively many metal parts originating in the tape-like metal mesh material 82 in the inner skin of the above-mentioned gasket 1, the above-mentioned gasket 1 to end 7 of the above-mentioned 1st exhaust pipe 3 The inner peripheral surface of the gasket body 41 can be protected from the end portion 7 of the first exhaust pipe 3 by the metal portion when externally fitted. That is, it is possible to suppress that part of the expanded graphite 51 falls off.

  Further, in the method of manufacturing the gasket 1, the composite forming step S2 is a bonding step S3A for bonding the tape-like expanded graphite 81 and the tape-like metal mesh material 82 in a mutually overlapping state. It contains. Here, as shown in FIG. 17, in the bonding step S3A, the tape-shaped metal mesh material 82 is made to bite into the tape-shaped expanded graphite 81.

  Specifically, as shown in FIG. 13, the tape-like expanded graphite 81 and the tape-like metal mesh material 82 are knurled by using an adhesion device 91 including a roll member 91 a. Apply. Thus, a part of the tape-like expanded graphite 81 is inserted into the gap of the tape-like metal mesh material 82 to bond the tape-like expanded graphite 81 and the tape-like metal mesh material 82.

  In this adhesive, as shown in FIG. 17, the metal mesh material 82 in the form of a tape is such that a portion of the metal wire 84 forming the tape is embedded in a portion of about 1/2 or more of its diameter. The tape-shaped expanded graphite 81 is made to bite into one side. Thus, the adhesive can be shaped to have a thickness on the order of 0.4 to 0.6 mm.

  According to such a configuration, it is possible to obtain the bonded body, that is, the composite body 83 in which the tape-like expanded graphite 81 and the tape-like metal mesh material 82 which are mutually overlapping are bonded. Therefore, when the composite 83 is wound in a spiral shape in the cylindrical body forming step S3, positional deviation of the tape-shaped metal mesh material 82 with respect to the tape-shaped expanded graphite 81 is prevented, and processing accuracy is improved. You can raise it.

  In the bonding step S3A, since the tape-shaped metal mesh material 82 is made to bite into the tape-shaped expanded graphite 81, the bonding operation between the tape-shaped expanded graphite 81 and the tape-shaped metal mesh material 82 is simplified. Can be implemented. Moreover, since knurling is used here, it is possible to easily realize an improvement in the adhesion between the tape-like expanded graphite 81 and the tape-like metal mesh material 82.

  Further, in the method of manufacturing the gasket 1, it is possible to use another tape-shaped reinforcing member instead of the tape-shaped reinforcing member made of the tape-shaped metal mesh material 82. As this other tape-like reinforcing member, for example, the tape-like member 95 as shown in FIG. 18 is composed of a cylindrical metal mesh material 93 and a tape-like expanded graphite 94 surrounded by the mesh material. Be

  The tape-like member 95 overlaps the tape-like expanded graphite 81 to form a composite 96. In the composite body 96, as shown in FIG. 19, the tape-like member 95 has a metal wire 98 forming one side of the cylindrical metal mesh material 93 at about 1/2 or more of its diameter. The tape-like expansive graphite 94 can be bitten into so that the part is embedded.

  Further, in the composite 96, as shown in FIG. 19, the tape-like member 95 has a metal wire 99 forming the other side of the cylindrical metal mesh material 93, which is about 1/3 the diameter of the metal wire 99. The tape-shaped expansive graphite 94 can be bitten into such a portion so that the portion of the tape-like expansive graphite 81 can be bitten into so that a portion of about 2/3 of its diameter is embedded.

  For example, the tape-like member 95 is a tubular metal mesh material 93 in the form of a knitted fabric in which a metal wire having a diameter of about 0.15 mm is knitted by knitting, and the tape-like expansion is applied thereto. By accommodating the graphite 94, it is formed to have a thickness of about 0.3 to 0.5 mm. Thus, the composite 96 can be shaped to have a thickness on the order of 0.6 to 1.1 mm.

  In this case, on the inner peripheral surface of the gasket 1 obtained, the exposure of the metal portion derived from the cylindrical metal mesh material 93 in the reinforcing member of the gasket 1 can be relatively reduced, whereby When the gasket 1 is fitted on the end 7 of the first exhaust pipe 3, the load for causing the end 7 of the first exhaust pipe 3 to enter the gasket main body 41 is reduced, and the mounting ease is improved. Can be

  In addition, the gasket 1 can be manufactured while the cylindrical metal mesh material 93 is restrained by the tape-shaped expanded graphite 94. That is, the compression molding step S4 can be performed while holding the cylindrical metal mesh material 93 so as not to be biased as much as possible. Therefore, the gasket main body 41 can be effectively reinforced using the tape-like member 95 (the other tape-like reinforcing member).

1 Gasket (exhaust pipe joint seal body)
3 first exhaust pipe 4 second exhaust pipe 7 end of first exhaust pipe 11 first flange 12 second flange 41 gasket main body (main body)
51 Expanded Graphite 51a Expanded Graphite Layer 52 Reinforcement Member 53 First Sealed Part 54 Second Sealed Part 57 Another Reinforcement Member

Claims (4)

A tape-shaped expanded graphite is spirally wound and then compression-molded into an annular expanded graphite main body, and the main body is sealed to seal between the first exhaust pipe and the second exhaust pipe. An exhaust pipe joint seal body configured to be externally fitted to an end of the first exhaust pipe so as to be pressed by the first flange of the first exhaust pipe and the second flange of the second exhaust pipe. There,
A heat-resistant reinforcing member provided between expanded graphite layers formed to overlap in a radial direction of the main body by the tape-shaped expanded graphite,
The body is
A first seal portion provided on one axial end side of the main body and capable of being in pressure contact with the first flange;
It is provided on the other end side in the axial direction of the main body, and has a second seal portion that can be in pressure contact with the second flange,
The first seal portion and the second seal portion are made only of expanded graphite ,
The outermost expanded graphite layer has a bent portion in a cross-section including the axial center of the main body between the first seal portion and the second seal portion at an axial midway portion of the main body <br / > Exhaust fitting seal body characterized by   The exhaust pipe joint seal body according to claim 1, wherein the expanded graphite layer and the reinforcing member alternately have a cross-sectional shape overlapping each other in a radial direction of the main body.   The exhaust pipe joint seal body according to claim 1 or 2, further comprising another reinforcing member provided on an inner periphery of the main body so as to be exposed radially inward of the main body. . The first seal portion has a tapered seal surface for pressing against a portion of the first flange surface of the first flange;
The second seal portion has a tapered seal surface for pressing against a portion of the second flange surface of the second flange;
The first seal portion and the second seal portion are formed in a symmetrical shape with an outer peripheral portion provided between the first seal portion and the second seal portion in the main body. The exhaust pipe fitting seal body according to any one of claims 1 to 3, characterized in that:

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