JP4960913B2 - Propeller shaft and supporting device for the propeller shaft - Google Patents

Description

  The present invention relates to a propeller shaft of a vehicle, and relates to a support device that supports a propeller shaft on a vehicle body via an intermediate bearing.

  As this type of conventional propeller shaft support device, for example, the one described in Patent Document 1 below is known.

  Briefly, the propeller shaft support device includes an annular member attached to a floor member of a vehicle body, an elastic member fixed inside the annular member, and a propeller via a bearing inside the elastic member. A support member that rotatably supports the shaft, a stopper piece that abuts on one side surface of the bearing and positions and fixes the bearing, and an inner peripheral surface that is disposed at least on one side in the axial direction of the bearing. Is mainly composed of an annular seal member that is in contact with the outer peripheral surface of the stopper piece.

  The elastic member is formed in a substantially folded shape in cross section that opens to the rear side of the vehicle body, the outer peripheral annular portion is fixed to the inner peripheral surface of the annular member, and the inner peripheral annular portion is fixed to the outer peripheral surface of the support member. Has been.

  The stopper piece has a substantially U-shaped cross section, a small diameter portion press-fitted into the outer periphery of the propeller shaft, a flange portion formed radially outward from a tip edge of the small diameter portion, and an outer periphery of the flange portion And a large-diameter portion formed in the axial direction from the end edge to the bearing side.

  Therefore, the stopper piece rotates integrally with the propeller shaft as the propeller shaft rotates.

  An annular recess is formed on the outer periphery of the side end surface of the inner peripheral annular portion facing the stopper piece of the elastic member, and the diameter is increased toward the outer peripheral side of the large diameter portion of the stopper piece continuously with the annular recess. A tapered guide is provided.

  Furthermore, an enlarged diameter portion is formed on the inner peripheral edge of the side end surface so as to protrude toward the flange portion of the stopper piece.

That is, a part of the outer peripheral surface of the enlarged diameter portion is surrounded by the large diameter portion of the stopper piece, and a so-called labyrinth structure is formed by the enlarged diameter portion of the elastic member and the large diameter portion of the stopper piece. Has been. This labyrinth structure prevents intrusion of muddy water, rain water or car wash water from the outer peripheral side of the large diameter portion of the stopper piece into the small diameter portion of the stopper piece.
Japanese Patent Laying-Open No. 2006-250251 (FIGS. 1 and 2)

  However, in the conventional propeller shaft support device, the labyrinth structure prevents intrusion of muddy water or the like into the small diameter portion of the stopper piece, but a slight amount of muddy water or the like passes through the labyrinth structure to reduce the small diameter of the stopper piece. There is a risk of intrusion. For this reason, there exists a possibility that rust may generate | occur | produce on the outer peripheral surface of the small diameter part of the said stopper piece.

  Since the stopper piece rotates integrally with the propeller shaft as described above, the outer peripheral surface of the small diameter portion of the stopper piece in which rust has occurred slides on the inner peripheral surface of the annular seal member. The inner peripheral surface of the annular seal member is worn over time due to the rust.

  As a result, the sealing performance of the annular seal member is deteriorated, which may cause muddy water or rust to enter the bearing.

  The present invention has been devised in view of the above-described conventional technical problems, and prevents deterioration of the sealing performance of the annular seal member by preventing the occurrence of rust due to adhesion of muddy water or the like. The purpose is to prevent the intrusion of muddy water.

The present invention has been devised in view of the above-described conventional situation, and the invention according to claim 1 includes an annular member attached to a floor member of a vehicle body, and an elastic member fixed to the inside of the annular member. And a support member that rotatably supports the propeller shaft via a bearing inside the elastic member, and disposed on at least one side of the bearing in the axial direction and rotated on the outer peripheral surface of the shaft portion of the propeller shaft A propeller shaft support device comprising: an annular seal member that is slidably contacted;
The rust preventive portion is formed on the outer peripheral surface of the shaft portion with which the annular seal member abuts, and the rust preventive portion is formed by a cylindrical rust preventive member fitted to the outer peripheral surface of the shaft portion, and the cylindrical shape The rust preventive member is formed of a stainless material, and an engagement portion that engages with the shaft portion is formed at one end of the cylindrical rust preventive member, and the engagement portion is formed on the cylindrical rust preventive member. The bent portion is formed by bending one end portion inward, and the bent portion is sandwiched between a side end surface of the shaft portion and one side surface of the bearing facing the side end surface. It is characterized by the arrangement .

  In the present invention, the antirust portion is formed on the outer peripheral surface of the shaft portion or the inner peripheral surface of the support member with which the annular seal member abuts, so that the outer peripheral surface of the shaft portion or the inner peripheral surface of the support member is compared. Even if muddy water adheres, the generation of rust can be prevented.

  Therefore, when the propeller shaft rotates, it is possible to prevent wear of the contact surface of the annular seal member that contacts the outer peripheral surface of the shaft portion or the inner peripheral surface of the support member over time. For this reason, the deterioration of the sealing performance of the annular seal member is prevented, and intrusion of muddy water or the like into the bearing can be prevented.

  Embodiments of a propeller shaft support device according to the present invention will be described below in detail with reference to the drawings.

  The propeller shaft of the vehicle provided in this embodiment is applied to a vehicle that uses a four-wheel drive or front engine rear drive drive system, and has a first shaft connected to a transmission as shown in FIGS. A drive shaft 1, a driven shaft 2 that is a second shaft connected to a differential gear, a cardan joint 3 that is a joint portion connecting the drive shaft 1 and the driven shaft 2, and a cardan joint of the driven shaft 2 It is mainly composed of a support device 4 provided on the side 3 and fixed to, for example, the lower portion of the cross member, which is a floor member of the vehicle body not shown.

  In the drive shaft 1, an input side yoke 8 constituting a part of the cardan joint 3 is fixed to the rear end portion of a drive side tube 1a made of steel pipe from the axial direction by welding or the like.

  The driven shaft 2 has a stub shaft 9 to which the support device 4 is attached fixed to the front end portion of a driven tube 2a made of steel pipe from the axial direction by welding or the like, and on the distal end side of the stub shaft 9. A driven yoke 13 which is a connecting yoke connected to the input side yoke 8 is fixed.

  The stub shaft 9 is formed of an iron-based metal in a substantially step diameter shape, and has a medium diameter that is a shaft portion formed in a gradually smaller diameter in the axial direction from the large diameter portion 10 fixed to the front end portion of the driven tube 2a. It has a portion 11 and a small diameter portion 12. In addition, a large-diameter shaft portion 11a that is smaller in diameter than the large-diameter portion 10 and larger in diameter than the medium-diameter portion 11 is formed between the large-diameter portion 10 and the medium-diameter portion 11. Between the diameter shaft portion 11 a and the medium diameter portion 11, a medium diameter shaft portion 11 b that is smaller in diameter than the large diameter shaft portion 11 a and larger in diameter than the medium diameter portion 11 is formed.

  A radial ball bearing 22, which is a bearing that constitutes a part of the support device 4, is provided on the outer periphery of the medium diameter portion 11. Further, a substantially annular first dust cover 27 that prevents direct entry of dust and the like into the radial ball bearing 22 is press-fitted to the outer periphery of the large-diameter shaft portion 11a, and the medium-diameter shaft An annular seal member 21 formed in a ring shape with a rubber material on the outer periphery of the portion 11b and having a core material embedded therein is provided. A serration convex portion 12 a is formed on the outer peripheral surface of the small diameter portion 12.

  The first dust cover 27 is bent in a substantially U-shaped cross section with an iron-based metal, and has an inner peripheral portion 27a press-fitted into the large-diameter shaft portion 11a and a diameter from a rear end edge of the inner peripheral portion 27a. A flange portion 27b formed outward in the direction, and an outer peripheral portion 27c formed in the axial direction from the outer peripheral edge of the flange portion 27b toward the radial ball bearing 22 side. The inner peripheral portion 27a and the outer peripheral portion 27c are slightly bent outward in the radial direction at the radial ball bearing 22 side edge.

  That is, the first dust cover 27 is fixed to the outer periphery of the large-diameter shaft portion 11a so as to open toward the radial ball bearing 22 and rotates integrally with the stub shaft 9.

  The driven yoke 13 has a serration concave portion 13b formed in an inner axial direction at an end located on the radial ball bearing 22 side, and the serration convex portion 12a is serrated and coupled to the serration concave portion 13b, and the stub shaft 9 is connected to the stub shaft 9 by a nut 17 and a plug 18 fastened to a male screw portion 81 formed at the tip of the small-diameter portion 12.

  The driven-side yoke 13 is formed on the outer periphery of the radial ball bearing 22 side in a substantially stepped cross section that rises from the radial ball bearing 22 side toward the cardan joint 3 side, and is substantially a shaft portion. An L-shaped small-diameter step portion 14; a substantially L-shaped medium-diameter step portion 15 formed continuously from the small-diameter step portion 14 and having a diameter larger than the outer diameter of the small-diameter step portion 14; And a large-diameter step portion 16 formed continuously from the portion 15 and having a diameter larger than the outer diameter of the medium-diameter step portion 15.

  The small-diameter step portion 14 includes an annular small-diameter end portion 14a, a small-diameter flat portion 14c formed continuously from the small-diameter end portion 14a and having a larger diameter than the small-diameter end portion 14a, and the small-diameter flat portion. And a back surface portion 14d rising from the front end edge of 14c, and a substantially annular second dust which prevents the direct entry of dust and the like by closing the front end side of the radial ball bearing 22 in the small diameter flat surface portion 14c. A cover 28 is fixed, and a flange portion 28b described later of the second dust cover 28 is in contact with the back surface portion 14d.

  The second dust cover 28 is formed of an iron-based metal so as to have a substantially U-shaped cross section, and is press-fitted into the small-diameter flat portion 14c of the driven side yoke 13, and the front end of the inner peripheral portion 28a. The flange portion 28b is formed radially outward from the edge, and the outer peripheral portion 28c is formed axially from the outer peripheral edge of the flange portion 28b to the radial ball bearing 22 side. The inner peripheral portion 28a and the outer peripheral portion 28c are slightly bent outward in the radial direction at the radial ball bearing 22 side edge.

  That is, the second dust cover 28 is fixed to the outer periphery of the small-diameter flat portion 14c so as to open toward the radial ball bearing 22 and rotates integrally with the driven-side yoke 13.

  An annular seal member 20 is provided on the outer periphery of the small-diameter end portion 14a of the driven side yoke 13 and is formed in an annular shape with a rubber material and has a core material embedded therein.

  Each of the annular seal members 21 and 20 has recesses 21b and 20b formed on the inner peripheral surfaces 21a and 20a in the circumferential direction, and the recesses 21b and 20b are filled with grease G.

  That is, the annular seal members 21 and 20 are provided on the outer circumferences of the medium diameter shaft portion 11b and the small diameter end portion 14a, thereby preventing intrusion of muddy water or the like into the radial ball bearing 22. Further, the grease G suppresses the wear of the inner peripheral surfaces 21 a and 20 a of the annular seal members 21 and 20.

  The intermediate diameter step portion 15 is composed of an annular intermediate diameter flat surface portion 15a and a back surface portion 15b rising from the front edge of the intermediate diameter flat surface portion 15a. A water shielding plate 19 that blocks muddy water that has been splashed up and prevents entry into the radial ball bearing 22 is press-fitted. In addition, a groove 15c having an arcuate cross section is formed in the circumferential direction at a corner portion between the medium-diameter plane portion 15a and the back surface portion 15b.

  The cardan joint 3 is held by a cross shaft 31 interposed between the input side yoke 8 and the driven side yoke 13 and bearing holding holes 8a and 13c formed at the tip portions of the yokes 8 and 13, respectively. The needle shafts 32 and 32 support the journal shafts of the cross shaft 31 in a rotatable manner.

  As shown in FIGS. 1 and 2, the support device 4 is an attachment bracket 6 which is an annular member fixed to the lower part of the floor member of the vehicle body by a stud bolt or the like via a pair of left and right legs 6a, 6a. And a casing 7 which is a support member fixed to the inside of the mounting bracket 6 via an elastic member 5, and the radial ball bearing 22 held inside the casing 7.

  The leg portions 6a, 6a are formed in a substantially U shape, extend from both sides of the outer end portion of the mounting bracket 6 toward the cross member, and extend in a horizontal direction in a substantially folded shape from the extended end portions. The extended vehicle body mounting surfaces 6b, 6b are formed. Further, bolt insertion holes 6c and 6c are formed through both ends of the leg portions 6a and 6a through which stud bolts (not shown) fixed to the cross member are inserted.

  The elastic member 5 is formed by a rubber material so as to open toward the driven shaft 2 and has a substantially folded cross-section. The elastic member 5 is an inner periphery of a metal annular press-fitting fixing portion 6 d that is press-fitted and fixed to the inner periphery of the mounting bracket 6. The outer peripheral annular portion 5a is vulcanized and bonded to the surface, and the inner peripheral annular portion 5b is vulcanized and bonded to the outer peripheral surface of the casing 7.

  Further, a side surface portion 5c is formed on an opposing surface of the inner circumferential annular portion 5b of the elastic member 5 that faces the second dust cover 28, and the second dust cover 28 is formed on the inner peripheral edge of the side surface portion 5c. A small-diameter cylindrical portion 5d is formed so as to protrude in the axial direction toward the side.

  The small-diameter cylindrical portion 5d has an inner peripheral small-diameter portion 5e located on the side surface portion 5c side, and a minimum diameter formed continuously from the tip of the inner peripheral small-diameter portion 5e and smaller in diameter than the inner peripheral small-diameter portion 5e. It is composed of a portion 5f and an annular convex portion 5g formed to protrude outward in the radial direction at the tip of the minimum diameter portion 5f.

  Therefore, the outer peripheral portion 28c of the second dust cover 28 surrounds the outer periphery of the small-diameter cylindrical portion 5d of the elastic member 5 in the axial direction from the annular convex portion 5g side to the side surface portion 5c side. While preventing direct intrusion of muddy water or the like from the outside of the second dust cover 28, the side surface portion 5c of the elastic member 5 and the outer peripheral portion 28c of the second dust cover 28 facing the side surface portion 5c. A so-called labyrinth structure is formed by complicating an intrusion path from the gap C formed in the circumferential direction to the outer peripheral surface 14b of the small-diameter end portion 14a between the end edge and the small-diameter end portion 14a. Infiltration of muddy water and the like into the outer peripheral surface 14b is suppressed.

  The casing 7 is formed of a thin metal plate in a substantially cylindrical shape with a step diameter, and a large-diameter annular portion 7a formed on the driven shaft 2 side, and the large-diameter annular portion 7a toward the driven-side yoke 13 side. An intermediate diameter annular portion 7b formed continuously in the axial direction and having an inner peripheral surface abutting on an outer peripheral surface of an outer race 24 described later of the radial ball bearing 22, and the intermediate diameter annular portion 7b; The inner peripheral surface is composed of a small-diameter annular portion 7 c that abuts on the outer peripheral surface of the annular seal member 20.

  Further, a substantially annular third dust cover 29 that opens to the driven shaft 2 side is provided on the inner periphery of the large-diameter annular portion 7a.

  The third dust cover 29 is formed by bending an iron-based metal into a substantially U-shaped cross section and is press-fitted into the inner periphery of the large-diameter annular portion 7a of the casing 7, and the outer cylindrical portion An inner peripheral cylinder that extends radially inward from the front end edge of the portion 29a on the radial ball bearing 22 side, is bent toward the first dust cover 27, and has an inner peripheral surface in contact with the outer peripheral surface of the annular seal member 21 It is comprised from the shape part 29b.

  That is, the third dust cover 29 is fixed to the inner periphery of the large-diameter annular portion 7 a so as to open toward the first dust cover 27, and the outer cylindrical portion 29 a is the outer periphery of the first dust cover 27. A part of the portion 27c is surrounded.

  Accordingly, the outer periphery 27c of the first dust cover 27 prevents direct intrusion of muddy water from the rear side of the vehicle body, and the third dust cover 29 surrounds the outer periphery 27c of the first dust cover 27. Between the outer peripheral surface of the outer peripheral portion 27c of the first dust cover 27 and the inner peripheral surface of the outer peripheral cylindrical portion 29a of the third dust cover 29 from the gap C1 formed in the circumferential direction. A so-called labyrinth structure is formed by complicating the intrusion path to the outer peripheral surface 11c of the medium-diameter shaft portion 11b, and the infiltration of muddy water or the like into the outer peripheral surface 11c of the medium-diameter shaft portion 11b is suppressed. .

  The radial ball bearing 22 includes an inner race 23 fixed to the outer peripheral surface of the medium diameter portion 11 of the stub shaft 9, and the outer race 24 held on the inner peripheral side of the medium diameter annular portion 7b of the casing 7. , And a plurality of steel balls 25 that are rotatably held between arc-shaped holding grooves formed at substantially the center of the opposing surfaces of the races 23 and 24.

  An annular plate 30 is provided between the driven side yoke 13 and the radial ball bearing 22.

  The annular plate 30 is formed of a synthetic resin material or the like, and the other end surface of the inner race 23 of the radial ball bearing 22 facing the side end surface 14e of the small-diameter end portion 14a of the driven side yoke 7 and the side end surface 14e. The driven yoke 13 and the inner race 23 rotate together with the driven yoke 13 and the inner race 23. Further, when the driven yoke 13 rotates, the annular plate 30 is slightly delayed in rotation of the inner race 23 with respect to the driven yoke 13, and the other side surface 23 d of the inner race 23 is connected to the driven yoke. The frictional resistance generated by the slight displacement in the circumferential direction with respect to the side end surface 14e of the 13 small-diameter end portions 14a is reduced to suppress the generation of vibration and noise.

  Further, grease G is filled between both side surfaces of the radial ball bearing 22 and the opposing surfaces of the annular seal members 21 and 20 facing both side surfaces of the radial ball bearing 22.

  A cylindrical rust prevention member 34 that is a rust prevention portion is provided between the annular seal member 21 and the stub shaft 9, and a rust prevention portion is provided between the annular seal member 20 and the driven side yoke 13. A cylindrical rust preventive member 33 is provided.

  As shown in FIGS. 3 and 4 (a) and 4 (b), one cylindrical rust prevention member 34 is bent and formed into a substantially L-shaped cross section by a stainless material, for example, a rust prevention material. The cylindrical portion 34a press-fitted into the medium-diameter shaft portion 11b of the shaft 9 and the radial portion 34a of the tubular portion 34a are bent radially inward from the one end portion 34c on the radial ball bearing 22 side. It is comprised from the bending part 34b which is an engaging part contact | abutted to the side end surface 11d of a certain said medium diameter shaft part 11b.

  As shown in FIG. 3 and FIGS. 4A and 4B, the other cylindrical rust preventive member 33 is bent and formed into a substantially L-shaped cross section by a stainless steel material, for example, a stainless steel material. A cylindrical portion 33a press-fitted into the small-diameter end portion 14a of the side yoke 13, and one end portion 33c of the cylindrical portion 33a on the radial ball bearing 22 side are bent inward in the radial direction, and at the side end surface of the shaft portion. It is comprised from the bending part 33b which is an engaging part contact | abutted to the side end surface 14e of the said small diameter edge part 14a.

  That is, each of the cylindrical anticorrosive members 34 and 33 is attached to the stub shaft 9 and the driven side yoke 13 and rotates integrally therewith, and the stub shaft 9 and the driven side yoke 13 rotate. Sometimes, the outer peripheral surfaces 34d and 33d of the cylindrical portions 34a and 33a slide with the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20, respectively.

  Further, when the cylindrical portion 34a is attached to the medium-diameter shaft portion 11b, the bent portion 34b has a side end face 11d of the medium-diameter shaft portion 11b and one end of the bearing. The inner race 23 that is the side surface is held in a sandwiched state with the one side surface 23c.

  Further, when the cylindrical portion 33a is attached to the small diameter end portion 14a, the bent portion 33b is connected to the small diameter end of the driven side yoke 13 via the annular plate 30. The side end surface 14e of the portion 14a and the other side surface 23d of the inner race 23 which is one side surface of the bearing are held in a sandwiched state.

  Therefore, each of the cylindrical rust prevention members 34, 33 has the bent portions 34b, 33b between the side end surface 11d of the medium diameter shaft portion 11b and one side surface 23c of the inner race 23, or at the small diameter end. It is firmly fixed between the side end face 14e of the portion 14a and the other side face 23d of the inner race 23.

  Accordingly, each of the cylindrical rust preventive members 34 and 33 is used when the stub shaft 9 and the driven yoke 13 are rotated or when a load is applied to the stub shaft 9 and the driven yoke 13 in the axial direction. It is prevented from being displaced in the direction, and the outer peripheral surfaces 34d and 33d of the cylindrical portions 34a and 33a are maintained in contact with the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20, respectively. be able to.

  As a result, wear of the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20 due to axial displacement of the cylindrical rust preventive members 34 and 33 is prevented, and the annular seal members 21 and 20 are prevented. Improves durability.

  Further, during traveling of the vehicle, muddy water or the like comes in, and a small amount of muddy water or the like enters the inside of each labyrinth structure from the gaps C and C1, so that the cylindrical rust prevention members 34 and 33 Even if muddy water or the like adheres to the outer peripheral surfaces 34d and 33d of the cylindrical portions 34a and 33a, the generation of rust can be prevented.

  Therefore, when the cylindrical rust preventive members 34, 33 rotate together with the stub shaft 9 and the driven yoke 13, the cylindrical portions 34a, 33a of the cylindrical rust preventive members 34, 33 are rotated. It is possible to prevent wear of the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20 on which the outer peripheral surfaces 34d and 33d slide with time.

  As a result, the sealing performance of each of the annular seal members 21 and 20 is prevented from being lowered, and muddy water or the like can be prevented from entering the radial ball bearing 22.

  5 and 6 show a second embodiment of the present invention, and the basic configuration is substantially the same as that of the first embodiment. The difference is that each of the cylindrical anticorrosion members 34 and 33 is low. A friction material, for example, a polyacetal resin material is used.

  Further, the annular plate 30 provided between the bent portion 33b of the cylindrical rust preventive member 33 and the other end surface 23d of the inner race 23 is abolished, and the cylindrical rust preventive member 33 is folded. One side surface of the curved portion 33 b is in contact with the other side surface 23 d of the inner race 23.

  That is, the friction coefficient of the cylindrical rust preventive members 34 and 33 is smaller than the friction coefficient of both side surfaces 23 c and 23 d of the inner race 23 of the radial ball bearing 22.

  For this reason, for example, the cylindrical rust preventive member 33 rotates integrally with the driven yoke 13, and the other side surface 23d of the inner race 23 is slightly in the circumferential direction with respect to one side surface of the bent portion 33b. Even if the position is shifted, the frictional resistance generated between one side surface of the bent portion 33b and the other side surface 23d of the inner race 23 can be reduced.

  Therefore, since the bent portion 33b exhibits the same function and effect as the annular plate 30, the number of parts constituting the propeller shaft can be reduced, and the cost can be reduced.

  Further, in each of the cylindrical rust preventive members 34 and 33, the friction coefficient of the inner peripheral surface of the cylindrical portions 34a and 33a is smaller than the friction coefficient of the outer peripheral surfaces 11c and 14b of the medium diameter shaft portion 11b and the small diameter end portion 14a. The bent portions 34b and 33b are located between the side end surface 11d of the medium diameter shaft portion 11b and one side surface 23c of the inner race 23, or from the other side surface 23d of the inner race 23 and the side end surface of the small diameter end portion 14a. 14e is arranged in a sandwiched state and firmly fixed, so that it is prevented from being displaced in the axial direction.

  Therefore, the outer peripheral surfaces 34d and 33d of the cylindrical portions 34a and 33a can be maintained in contact with the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20, respectively.

  As a result, the wear of the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20 due to the axial displacement of the cylindrical antirust members 34 and 33 is prevented, and the annular seal members 21 and 20 Durability is improved.

  Further, muddy water or the like enters the inside of each labyrinth structure from the gaps C and C1, and muddy water or the like adheres to the outer peripheral surfaces 34d and 33d of the cylindrical portions 34a and 33a of the cylindrical rust prevention members 34 and 33. Even if it does, generation | occurrence | production of rust can be prevented.

  Accordingly, when the cylindrical rust preventive members 34 and 33 rotate together with the stub shaft 9 and the driven yoke 13, the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20 are changed over time. Thus, the wear of each of the annular seal members 21 and 20 is prevented from being deteriorated, and the intrusion of muddy water or the like into the radial ball bearing 22 can be prevented.

  7 and 8 show a third embodiment of the present invention, in which the other end portions 34e and 33e of the cylindrical anticorrosion members 34 and 33 are provided with projecting portions 34f and 33f projecting outward in the radial direction. It is a thing.

  The projecting portions 34f and 33f are formed by bending outward from the other end portions 34e and 33e of the cylindrical portions 34a and 33a in the radial direction, and outer peripheral edges of the first and second dust covers 27 and 28. A shape that is located on the outer peripheral side from the edges of the inner peripheral portions 27a, 28a and shields a part of the opposing side surfaces of the annular seal members 21, 20 facing the first and second dust covers 27, 28. It has become.

  Further, due to the protrusions 34f and 33f, the gap between the inner peripheral surface 29c of the inner peripheral cylindrical portion 29b and the outer peripheral surface 34d of the cylindrical portion 34a, the inner peripheral surface 7d of the small-diameter annular portion 7c, and the cylinder A gap between the outer peripheral surface 33d of the shape portion 33a is reduced.

  Therefore, the labyrinth structure is further complicated, and muddy water or the like can be prevented from entering the outer peripheral surfaces 34d and 33d of the cylindrical portions 34a and 33a from the gaps C and C1.

  9 and 10 show a fourth embodiment of the present invention, in which annular portions 34g and 33g are formed on the outer peripheral edges of the projecting portions 34f and 33f of the cylindrical rust preventive members 34 and 33, respectively.

  The annular portions 34g and 33g are bent in the axial direction from the outer peripheral edges of the projecting portions 34f and 33f to the flange portions 27b and 28b of the first and second dust covers 27 and 28, respectively. The inner peripheral surface 29c of the inner peripheral cylindrical portion 29b of the third dust cover 29 and the inner peripheral portion 27a of the first dust cover 27 so as to cover the edges of the inner peripheral portions 27a, 28a of the dust covers 27, 28. It is arranged between the end edges and between the inner peripheral surface 7 d of the small-diameter annular portion 7 c of the casing 7 and the end edge of the inner peripheral portion 28 a of the second dust cover 28.

  For this reason, a gap between the inner peripheral surface 29c of the inner peripheral cylindrical portion 29b of the third dust cover 29 and the edge of the inner peripheral portion 27a of the first dust cover 27 by the annular portions 34g and 33g, A gap between the inner peripheral surface 7d of the small-diameter annular portion 7c of the casing 7 and the edge of the inner peripheral portion 28a of the second dust cover 28 is reduced.

  Therefore, the labyrinth structure is further complicated, and muddy water or the like can be further prevented from entering the outer peripheral surfaces 34d and 33d of the cylindrical portions 34a and 33a from the gaps C and C1.

  FIG. 11 shows a fifth embodiment of the present invention, between the inner periphery of the third dust cover 29 and the annular seal member 21, the inner periphery of the small-diameter annular portion 7 c of the casing 7, and the annular seal member 20. The cylindrical rust prevention members 34 and 33 are provided between the outer periphery.

  That is, the cylindrical rust preventive members 34 and 33 are formed in a substantially cylindrical shape and are press-fitted and fixed to the inner periphery of the inner peripheral cylindrical portion 29 b of the third dust cover 29, and the small-diameter annular shape of the casing 7. It is press-fitted and fixed to the inner periphery of the portion 7c. The annular seal member 21 is fixed to the outer periphery of the medium diameter shaft portion 11b, and the annular seal member 20 is fixed to the outer periphery of the small diameter end portion 14a.

  Therefore, the annular seal members 21 and 20 are formed with the lip portions 21c and 20c on the outer peripheral surfaces 21e and 20e that are in contact with the inner peripheral surfaces of the cylindrical antirust members 34 and 33, respectively. .

  Therefore, when the stub shaft 9 and the driven side yoke 13 rotate as a unit, wear of the outer peripheral surfaces 21e and 20e of the annular seal members 21 and 20 with time is prevented, and the annular seal members are prevented. 21 and 20 can be prevented from being deteriorated, and muddy water or the like can be prevented from entering the radial ball bearing 22.

  12 and 13 show a sixth embodiment of the present invention, wherein the first and second dust covers 27 and 28 are made of a rust preventive material such as stainless steel, and the first and second dust covers. 27, 28 are extended to the radial ball bearing 22 side, and between the annular seal member 21 and the stub shaft 9, and between the annular seal member 20 and the driven side yoke 13, a small diameter step. It is arranged between the part 14. Further, bent portions 27e and 28e are formed at the extended edges of the inner peripheral portions 27a and 28a.

  For this reason, the large-diameter shaft portion 11a of the stub shaft 9 is formed to have the same diameter as the medium-diameter shaft portion 11b, and the outer periphery of the large-diameter shaft portion 11a and the medium-diameter shaft portion 11b having the same diameter, An inner peripheral portion 27a of the first dust cover 27 is encapsulated. Further, the small-diameter flat surface portion 14c of the driven side yoke 13 is formed to have the same diameter as the small-diameter end portion 14a. The inner peripheral part 28a of 28 is encapsulated.

  That is, when the first and second dust covers 27, 28 rotate together with the stub shaft 9 and the driven yoke 13, the outer peripheral surfaces 27d, 28d of the inner peripheral portions 27a, 28a The annular seal members 21 and 20 slide on the inner peripheral surfaces 21a and 20a.

  The bent portions 27e and 28e are bent inward in the radial direction from the extended edges of the inner peripheral portions 27a and 28a, and the side end face 11d of the medium diameter shaft portion 11b of the stub shaft 9 and the inner race 23 is disposed between the one side surface 23 c of the inner race 23 and between the other side surface 23 d of the inner race 23 and the side end surface 14 e of the small-diameter end portion 14 a of the driven side yoke 13. The annular plate 30 is provided between the bent portion 28e and the other side surface 23d of the inner race 23.

  Therefore, the first and second dust covers 27 and 28 have bent portions 27e and 28e between the side end surface 11d of the medium diameter shaft portion 11b and one side surface 23c of the inner race 23, or between the inner race 23 and the inner race 23. Since it is firmly fixed between the other side surface 23d and the side end surface 14e of the small-diameter end portion 14a and is prevented from being displaced in the axial direction, the outer peripheral surfaces 27d and 28d of the inner peripheral portions 27a and 28a The state which contact | abutted to the internal peripheral surfaces 21a and 20a of the annular seal members 21 and 20 can be maintained.

  As a result, the wear of the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20 due to the axial displacement of the cylindrical antirust members 34 and 33 is prevented, and the annular seal members 21 and 20 Durability is improved.

  That is, even if muddy water or the like adheres to the first and second dust covers 27 and 28 constituting the labyrinth structure, the generation of rust can be prevented.

  Therefore, when the first and second dust covers 27 and 28 are rotated by the stub shaft 9 and the driven yoke 13, wear of the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20 is prevented. It is possible to prevent the sealing performance of the annular seal members 21 and 20 from being lowered, and to prevent muddy water or the like from entering the radial ball bearing 22.

  14 and 15 show a seventh embodiment of the present invention, in which the flange portions 27b, 28b of the first and second dust covers 27, 28 are formed with axial convex portions 27f, 28f which are convex portions. Is.

  The axial convex portions 27f and 28f are formed so as to protrude in a cross-sectional shape in the axial direction from the substantially intermediate position in the radial direction of the flange portions 27b and 28b to the radial ball bearing 22 side, and are substantially annular along the circumferential direction. Is formed. The axial convex portion 27f is disposed slightly on the inner peripheral side from the edge of the inner peripheral cylindrical portion 29b of the third dust cover 29, and the axial convex portion 28f is formed on the casing 7. It arrange | positions so that the front-end edge of the small diameter annular part 7c may be opposed.

  That is, due to the axial projections 27f and 28f, the gap between the end edge of the inner peripheral cylindrical portion 29b and the opposite side surface of the flange portion 27b facing the end edge, or the small-diameter annular portion 7c Since the gap between the leading edge and the opposite side surface of the flange portion 28b facing the leading edge becomes small, the labyrinth structure is complicated, and the inner peripheral portions 27a, 28a are formed from the gaps C, C1. The intrusion of muddy water or the like into the outer peripheral surfaces 27d, 28d can be suppressed.

  Furthermore, even if muddy water or the like adheres to the outer peripheral surfaces 27d and 28d of the inner peripheral portions 27a and 28a, the generation of rust can be prevented.

  Accordingly, when the first and second dust covers 27 and 28 are rotated together with the stub shaft 9 and the driven yoke 13, the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20 are changed over time. Therefore, the wear of the annular seal members 21 and 20 is prevented from being deteriorated, and the intrusion of muddy water or the like into the radial ball bearing 22 can be prevented.

  FIGS. 16 and 17 show an eighth embodiment of the present invention, wherein radial convex portions 27g and 28g, which are convex portions, are provided on the inner peripheral portions 27a and 28a of the first and second dust covers 27 and 28, respectively. It is a thing.

  The radial projections 27g and 28g are formed on the inner peripheral portions 27a and 28a on the flange portions 27b and 28b side so as to project outward in the radial direction in a cross-sectional shape, and are formed in a substantially annular shape along the circumferential direction. Yes.

  For this reason, the radial convex portions 27g and 28g are provided between the inner peripheral surface 29c of the inner peripheral cylindrical portion 29b and the outer peripheral surface 27d of the inner peripheral portion 27a, or the inner peripheral surface 7d of the small-diameter annular portion 7c. And the outer peripheral surface 28d of the inner peripheral portion 28a become smaller.

  Accordingly, the labyrinth structure is complicated, and the inner peripheral surfaces 21a of the annular seal members 21 and 20 of the inner peripheral portions 27a and 28a of the first and second dust covers 27 and 28 from the gaps C and C1. , 20a can be prevented from entering the outer peripheral surfaces 27d, 28d.

  18 and 19 show a ninth embodiment of the present invention, wherein the flange portions 27b and 28b of the first and second dust covers 27 and 28 are provided with the axial convex portions 27f and 28f, and the inner peripheral portion. 27a and 28a are provided with the radial convex portions 27g and 28g.

  Accordingly, the labyrinth structure is further complicated, and comes into contact with the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20 of the first and second dust covers 27 and 28 from the gaps C and C1. Infiltration of muddy water or the like into the outer peripheral surfaces 27d and 28d of the inner peripheral portions 27a and 28a can be further suppressed.

  20 and 21 show the tenth embodiment of the present invention, and the outer peripheral surface of the small-diameter end portion 14a of the driven-side yoke 13 that is a part that contacts the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20. 14b and the outer peripheral surface 11c of the medium-diameter shaft portion 11b of the stub shaft 9 are subjected to rust prevention treatment by, for example, plating.

  Therefore, according to this embodiment, muddy water or the like comes during traveling of the vehicle and the like, inside the labyrinth structure formed by the second dust cover 28 and the small diameter cylindrical portion 5d of the elastic member 5, Even if a small amount of muddy water permeates and adheres to the outer peripheral surface 14b of the small-diameter end portion 14a, the occurrence of rust on the outer peripheral surface 14b of the small-diameter end portion 14a can be prevented. In addition, muddy water or the like slightly enters the labyrinth structure formed by the first dust cover 27 and the third dust cover 29, and muddy water or the like adheres to the outer peripheral surface 11c of the medium-diameter shaft portion 11b. Even if it does, generation | occurrence | production of the rust of the said outer peripheral surface 11c can be prevented.

  Therefore, when the driven yoke 13 rotates and the stub shaft 9 rotates, the annular seal member slides on the outer peripheral surface 14b of the small diameter end portion 14a and the outer peripheral surface 11c of the medium diameter shaft portion 11b. By preventing the inner peripheral surfaces 21a and 20a of the 21 and 20 from being worn over time, the sealing performance can be prevented from being lowered, and muddy water or the like can be prevented from entering the radial ball bearing 22.

  22 and 23 show an eleventh embodiment of the present invention, in which the outer peripheral surface 14b to the side end surface 14e of the small diameter end portion 14a of the driven side yoke 13 and the outer peripheral surface of the medium diameter shaft portion 11b of the stub shaft 9 are shown. 11c is subjected to, for example, electroless nickel fluororesin plating, which is a rust prevention treatment and a low friction treatment.

  Further, the side end surface 14e of the small diameter end portion 14a is in contact with the other side surface 23d of the inner race 23, and between the side end surface 14e of the small diameter end portion 14a and the other side surface 23d of the inner race 23. The annular plate 30 that has been arranged is eliminated.

  That is, the friction coefficient of the side end surface 14e of the small diameter end portion 14a is smaller than the friction coefficient of the other side surface 23d of the inner race 23.

  For this reason, even if the driven side yoke 13 rotates and the other side surface 23d of the inner race 23 slightly shifts in the circumferential direction with respect to the side end surface 14e of the driven side yoke 13, the side end surface 14e The frictional resistance generated between the other side surface 23d can be reduced.

  Therefore, the number of parts constituting the propeller shaft is reduced, and the cost can be reduced.

  In addition, muddy water or the like enters the inside of each labyrinth structure from the gaps C and C1, and muddy water or the like adheres to the outer peripheral surface 14b of the small diameter end portion 14a or the outer peripheral surface 11c of the medium diameter shaft portion 11b. Also, the occurrence of rust can be prevented.

  Therefore, when the driven yoke 13 and the stub shaft 9 rotate, the annular seal members 21 and 20 slide on the outer peripheral surface 14b of the small diameter end portion 14a and the outer peripheral surface 11c of the medium diameter shaft portion 11b. Wear over time of the inner peripheral surfaces 21a and 20a can be prevented.

  As a result, it is possible to prevent the sealing performance of each of the annular seal members 21 and 20 from being lowered, and to prevent muddy water or the like from entering the radial ball bearing 22.

  FIG. 24 shows a twelfth embodiment of the present invention, and the inner peripheral surface 29c of the inner peripheral small diameter portion 29b of the third dust cover 29 that contacts the outer peripheral surfaces 21e, 20e of the annular seal members 21, 20 respectively. The inner surface 7d of the small-diameter annular portion 7c of the casing 7 is subjected to rust prevention treatment by, for example, plating.

  Therefore, according to this embodiment, muddy water or the like comes during traveling of the vehicle and the like, inside the labyrinth structure formed by the second dust cover 28 and the small diameter cylindrical portion 5d of the elastic member 5, Even if a small amount of muddy water permeates and adheres to the inner peripheral surface 7d of the small-diameter annular portion 7c, the occurrence of rust on the inner peripheral surface 7d of the small-diameter annular portion 7c can be prevented. Further, a slight amount of muddy water enters the labyrinth structure formed by the first dust cover 27 and the third dust cover 29, and muddy water or the like enters the inner peripheral surface 29c of the inner peripheral small diameter portion 29b. Even if it adheres, generation | occurrence | production of the rust of the internal peripheral surface 29c of the said internal peripheral small diameter part 29b can be prevented.

  Therefore, when the driven yoke 13 rotates and the stub shaft 9 rotates, the annular slides on the inner peripheral surface 7d of the small-diameter annular portion 7c and the inner peripheral surface 29c of the inner peripheral small-diameter portion 29b. By preventing the outer peripheral surfaces 21e and 20e of the seal members 21 and 20 from being worn over time, the sealing performance can be prevented from being lowered, and muddy water or the like can be prevented from entering the radial ball bearing 22.

  25 and 26 show a thirteenth embodiment of the present invention, in which an annular seal member 26 is provided on the outer periphery of the small diameter end portion 14a of the driven side yoke 13. FIG.

  That is, since the annular seal members 20 and 26 are provided on the outer periphery of the small diameter end portion 14a, the small diameter end portion 14a of the driven side yoke 13 extends in the axial direction, and the small diameter flat surface portion 14c It is shorter in the axial direction. The small-diameter cylindrical portion 5d of the elastic member 5 and the small-diameter annular portion 7c of the casing 7 extend to the front end side in the same manner as the small-diameter end portion 14a, and the small-diameter cylindrical portion 5d of the elastic member 5 The minimum diameter portion 5f is set to the same diameter as the inner peripheral small diameter portion 5e.

  Accordingly, the outer peripheral surface 14b of the small-diameter end portion 14a extending in the axial direction of the driven-side yoke 13 is covered with the double annular seal members 20 and 26, so that the sealing performance is further improved, and the small-diameter end Rust generation can be prevented over a wide range in the axial direction of the outer peripheral surface 14b of the portion 14a. Further, since the grease G is filled between the annular seal members 20 and 26, the waterproof property is improved.

  For this reason, when the driven side yoke 13 is rotated, the inner peripheral surfaces 20a and 26a of the annular seal members 20 and 26 are prevented from being worn, so that muddy water or the like can enter the radial ball bearing 22 more effectively. It can be surely prevented.

  27 and 28 show a fourteenth embodiment of the present invention, in which outer annular grooves 24a, 24a and inner races 23 are formed on both axial sides of the inner peripheral surface of the outer race 24 constituting the radial ball bearing 22. Inner annular grooves 23a, 23a are formed on both axial sides of the outer peripheral surface, and the sliding seal members 35, 35 are press-fitted between the outer annular grooves 24a, 24a and the inner annular grooves 23a, 23a. .

  The sliding seal members 35, 35 include annular holding members 36, 36 fixed to the outer annular grooves 24 a, 24 a of the outer race 24, and an annular seal portion fixed to the holding members 36, 36. 38, 38 and annular sealing members 37, 37 fixed to the inner annular grooves 23a, 23a of the inner race 23.

  The holding members 36, 36 are bent in an approximately L shape in cross section with an iron-based metal and fixed to the inner peripheral surface of the outer race 24, and one end of the outer peripheral portions 36 a, 36 a It is comprised from the flange parts 36b and 36b bent to the radial inside.

  The seal portions 38 and 38 are formed of a rubber material, and an outer peripheral surface and a side surface on one end side are opposed to an inner peripheral surface of the outer peripheral portions 36a and 36a of the holding members 36 and 36 and a side surface on the one end side. A space portion 39 is provided on the side surface on the other end side by vulcanization bonding to the side surface.

  The sealing members 37, 37 are disposed opposite to the holding members 36, 36 via the seal portions 38, 38, and are bent in an approximately L shape in cross section by an iron-based metal, The inner circumferential portions 37a and 37a are fixed to the annular grooves 23a and 23a, and flange portions 37b and 37b are formed to be bent radially outward from one end portions of the inner circumferential portions 37a and 37a.

  Of the space 39 provided in the seal portion 38, 38, the space 39 a formed between the sealing member 37, 37 and the seal portion 38, 38 facing the seal member 38, 38 is filled with grease G. Therefore, it is possible to prevent an increase in frictional resistance between the sealing members 37 and 37 that rotate integrally with the stub shaft 9 and the seal portions 38 and 38 that face the sealing members 37 and 37. Yes.

  Therefore, since the annular seal members 21 and 20 and the sliding seal members 35 and 35 provide a double sealing function, the sealing performance is improved and the intrusion of muddy water or the like into the radial ball bearing 22 is more reliably performed. Can be prevented.

  29 and 30 show a fifteenth embodiment of the present invention, in which the outer annular grooves 24a, 24a provided on both side surfaces of the inner circumferential surface of the outer race 24 are formed on the outer circumferential grooves having a stepped cross section. 24b, 24b is formed, and the outer peripheral ends 37c, 37c of the flange portions 37b, 37b of the sealing members 37, 37 are extended outward from the outer peripheral portions 36a, 36a of the holding members 36, 36. The dynamic seal members 35 and 35 are press-fitted.

  The outer peripheral end portions 37c and 37c of the flange portions 37b and 37b of the sealing members 37 and 37, the outer peripheral annular grooves 24b and 24b of the outer race 24 facing the outer peripheral end portions 37c and 37c, and the holding members 36 and 36, respectively. A labyrinth structure is formed by the outer peripheral portions 36a, 36a.

  Therefore, as in the fourteenth embodiment, the annular seal members 21 and 20 and the sliding seal members 35 and 35 provide a double sealing function, and the outer peripheral side of the sliding seal members 35 and 35. The waterproof property is further improved, and intrusion of muddy water or the like into the radial ball bearing 22 can be prevented.

  31 and 32 show a sixteenth embodiment of the present invention, wherein the outer peripheral ends 37c, 37c of the flange portions 37b, 37b of the sealing members 37, 37 are connected to the outer peripheral portions 36a, 36a of the holding members 36, 36, respectively. The sliding seal members 35, 35 that are bent outward and placed in a fitted state are press-fitted into both side surfaces of the radial ball bearing 22.

  By bending outer peripheral ends 37c, 37c of the flange portions 37b, 37b of the sealing members 37, 37, the labyrinth structure in the fourteenth embodiment is further complicated, and the flange portions 37b, 37b, Since the grease G can be filled in the bent portion 37b, the waterproof property is improved.

  Accordingly, as in the fourteenth and fifteenth embodiments, the annular seal members 21 and 20 and the sliding seal members 35 and 35 provide a double sealing function and the sliding seal members 35 and 35. The water resistance of the outer peripheral side surface of the outer peripheral surface of the outer peripheral side of the radial ball bearing 22 can be further improved, and muddy water or the like can be prevented from entering the radial ball bearing 22.

  33 and 34 show a seventeenth embodiment of the present invention, in which annular concave grooves 24c and 24c extending in an L-shaped cross section are formed on the outer peripheral sides of both side surfaces of the outer race 24, and The radial ball bearing 22 includes the sliding seal members 35, 35 formed by extending the outer peripheral ends 37c, 37c of the flange portions 37b, 37b of the sealing members 37, 37 in the embodiment so as to be bent outward. The outer peripheral end portions 37c and 37c formed by bending the flange portions 37b and 37b of the sealing members 37 and 37 are fitted to the outer peripheral portions of the annular concave grooves 24c and 24c. .

  The annular concave grooves 24c, 24c formed on the outer peripheral sides of both side surfaces of the outer race 24, and the outer peripheral convex portions 24d formed on the inner peripheral side of the annular concave grooves 24c, 24c and extending in the axial direction. 24d and flange portions 37b and 37b of the sealing members 37 and 37, and outer peripheral end portions 37c and 37c bent with the flange portions 37b and 37b, on the outer side of the sliding seal members 35 and 35, A more complicated labyrinth structure is formed, and grease G can be filled between the flange portions 37b and 37b of the sealing members 37 and 37 and the bent outer peripheral end portions 37c and 37c.

  Therefore, as in the fourteenth to sixteenth embodiments, the annular seal members 21 and 20 and the sliding seal members 35 and 35 provide a double sealing function, and on both side surfaces of the radial ball bearing 22. The waterproofness of the outer side surface of the outer race 24 is further improved, and entry of muddy water or the like into the radial ball bearing 22 can be prevented more reliably.

  35 and 36 show an eighteenth embodiment of the present invention, in which inner annular grooves 23a, 23a formed on both side surfaces of the inner race 23 are deepened, and shafts are formed on the side surfaces of the inner annular grooves 23a, 23a. The sliding seal members 35, 35 having inner circumferential convex portions 23b, 23b extending in the direction, and annular concave portions 35a, 35a provided on opposing surfaces facing the inner circumferential convex portions 23b, 23b are provided. The outer annular grooves 24a and 24a and the inner annular grooves 23a and 23a formed on both side surfaces of the radial ball bearing 22 are press-fitted.

  The annular recesses 35a, 35a are formed between the inner peripheral side end surfaces of the flange portions 36b, 36b of the holding members 36, 36 and the outer peripheral surfaces of the inner peripheral portions 37a, 37a of the sealing members 37, 37. The annular recesses 35a and 35a are fitted into the inner peripheral projections 23b and 23b in a loosely fitted state.

  Accordingly, as in the fourteenth to seventeenth embodiments, the annular seal members 21 and 20 and the sliding seal members 35 and 35 provide a double sealing function, and the inner peripheral convex portion 23b, A labyrinth structure is formed between the circular recess 23a and the annular recesses 35a and 35a, the inner side sealability of the radial ball bearing 22 is further improved, and muddy water and the like enter the radial ball bearing 22 Can be prevented.

  37 and 38 show a nineteenth embodiment of the present invention, in which a space portion 39 formed between the sealing members 37, 37 and the seal portions 38, 38 is not filled with grease G. 39b is filled with grease G.

  Therefore, the space 39b is sealed with the grease G, and the increase in the frictional resistance between the sealing members 37 and 37 and the seal portions 38 and 38 when the radial ball bearing 22 rotates is further prevented and waterproof. Is further improved.

  39, 40, and 41 show a twentieth embodiment of the present invention, in which the side surface portion 5c between the cross member of the vehicle body and the small diameter portion 12 of the stub shaft 9 in the elastic member 5, and the side surface A pair of discharge passages 40, 40 are formed in a portion of the portion 5c facing each other through the small diameter portion 12 of the stub shaft 9.

  The discharge passages 40, 40 are provided so as to extend outward from the side surface portion 5c and penetrate the outer peripheral surface of the inner peripheral annular portion 5b.

  Therefore, the discharge passages 40, 40 can guide the muddy water and the like flying to the side surface portion 5c to the rear side of the vehicle body, and the discharge passages 40, 40 are formed in the portion where the intrusion of muddy water is the most. Thus, since muddy water or the like can be guided more effectively to the driven shaft 2 side, it is possible to prevent muddy water or the like from entering the outer peripheral surface of the small diameter step portion 14 of the stub shaft 9.

  42 and 43 show a twenty-first embodiment of the present invention, in which lip portions 21c and 20c are formed on the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20, respectively. Further, the recesses 21d and 20d formed between the lip portions 21c and 20c are filled with grease G.

  Accordingly, the durability of the annular seal members 21 and 20 is improved, and when the driven side yoke 13 and the stub shaft 9 are rotated, the outer peripheral surface 14b of the small diameter end portion 14a of the driven side yoke 13 and the By reducing the frictional resistance of the inner peripheral surfaces 21a and 20a of the annular seal members 21 and 20 that slide with the outer peripheral surface 11c of the medium diameter shaft portion 11b of the stub shaft 9, it is possible to prevent a decrease in sealing performance. .

  44 and 45 show a twenty-second embodiment of the present invention, which is narrow between the side end surface of the small diameter end portion 14a of the driven side yoke 13 and the side surface of the radial ball bearing 22 facing the side end surface. The annular plate 30 provided in the holding state is extended to the outer peripheral side.

  That is, the outer peripheral surface 30a of the annular plate 30 is more outer than the inner peripheral surface 20a of the annular seal member 20 and the outer peripheral surface 14b of the small-diameter end portion 14a of the driven-side yoke 13 that slides on the inner peripheral surface 20a. It extends to.

  Accordingly, muddy water or the like enters between the side surface portion 5c of the elastic member 5 and the opposite end portion of the outer peripheral portion 28c of the second dust cover 28 facing the side surface portion 5c, and the small diameter of the driven side yoke 13 is reduced. Even if muddy water or the like enters the annular seal member 26 that slides with the end portion 14 a and the front side surface of the radial ball bearing 22, the muddy water or the like enters the radial ball bearing 22 by the annular plate 30. Can be prevented.

  46 and 47 show a twenty-third embodiment of the present invention, in which the elastic member 5 is disposed so as to be inverted in the axial direction, and between the outer peripheral annular portion 5a and the inner peripheral annular portion 5b of the elastic member 5. The opening 5h is directed to the front side of the vehicle body.

  The casing 7 is provided to rise to the drive shaft 1 side, and the third dust cover 29 is open to the front of the vehicle body. The first dust cover 27 is press-fitted into the outer periphery of the small-diameter flat portion 14 c of the stub shaft 9, and the second dust cover 28 is press-fitted into the outer periphery of the large-diameter shaft portion 11 a of the stub shaft 9. The opening 5h is located on the rear side of the vehicle body from the installation position of the first and third dust covers 27 and 29.

  Accordingly, muddy water or the like flying from the front of the vehicle body is received in the form collected in the opening 5h. Therefore, it is possible to suppress the backflow of muddy water and the like to the outer peripheral surface side of the outer peripheral portion 27c of the first dust cover 27 provided in front of the vehicle body from the opening 5h, and the outer peripheral portion 27c of the first dust cover 27 Since muddy water or the like adhering to the outer peripheral surface is rotated integrally with the small-diameter end portion 14a of the driven-side yoke 13 and scattered to the outer peripheral side by centrifugal force, the small-diameter end portion 14a of the driven-side yoke 13 is scattered. Infiltration of muddy water or the like into the outer peripheral surface 14b can be suppressed.

  48, 49 and 50 show a twenty-fourth embodiment of the present invention, in which an annular shielding portion 50 is provided on the outer peripheral surface of the inner peripheral annular portion 5b of the elastic member 5 in the twenty-second embodiment. Is.

  The shielding part 50 is formed in a tapered shape from the outer peripheral surface of the inner peripheral annular part 5 b of the elastic member 5 toward the outer peripheral annular part 5 a, and the outer peripheral end part 50 a is the outer peripheral annular part 5 a of the elastic member 5. It extends outward.

  Therefore, the shielding unit 50 prevents intrusion of muddy water and the like and foreign matter into the opening 5h, and elastically deforms the muddy water and the like to the outside by water pressure such as muddy water, so that the adhering muddy water and the like are outward. In order to scatter, adhesion of muddy water etc. to the outer peripheral surface of the outer peripheral portion 27c of the first dust cover 27 provided on the inner peripheral side can be suppressed. Further, since the first dust cover 27 rotates integrally with the driven side yoke 13, the muddy water or the like adhering to the outer peripheral surface of the outer peripheral portion 27c is scattered to the outer peripheral side, so that the driven side yoke 13 Infiltration of muddy water or the like into the outer peripheral surface 14b of the small diameter end portion 14a can be suppressed.

  51, 52 and 53 show a twenty-fifth embodiment of the present invention, wherein the second dust cover 28 provided on the outer periphery of the small-diameter end portion 14a of the driven-side yoke 13 is eliminated, and the elastic member An annular shield 51 extending from the front end portion 5i of the small diameter cylindrical portion 5d to the front side of the vehicle body is formed.

  The shield 51 is tapered from the front end portion 5i of the small diameter cylindrical portion 5d toward the back end portion 14f of the back end portion 14d of the small diameter step portion 14 of the driven side yoke 13 facing the front end portion 5i. The outer peripheral end portion 51 a extends outward from the back surface portion 14 d of the small diameter step portion 14. Further, by providing the shield 51, an opening guide portion 52 is formed between the outer peripheral side surface 51b of the shield 51 and the side surface portion 5c.

  Then, the muddy water or the like that has entered the opening guide portion 52 is guided outward through the outer peripheral side surface 51 b of the shield 51. At this time, since the shield 51 receives water pressure such as muddy water on the outer peripheral side surface 51b, the inner peripheral side surface 51c comes into contact with the back end 14f due to elastic deformation.

  Therefore, in order to shield the gap between the front end portion 5i of the small diameter cylindrical portion 5d and the back surface portion 14d of the small diameter step portion 14 of the driven side yoke 13, muddy water on the outer peripheral surface 14b of the small diameter end portion 14a, etc. By preventing the intrusion of rust, the generation of rust on the outer peripheral surface 14b can be prevented.

  54 and 55 show a twenty-sixth embodiment of the present invention, in which the small-diameter cylindrical portion 5d of the elastic member 5 is eliminated, the second dust cover 28 is eliminated, and the small-diameter annular portion of the casing 7 is eliminated. An annular retainer 53 is provided on the outer peripheral surface of 7c, and an annular seal portion 54 is provided between the retainer 53 and the back surface portion 14d of the small diameter step portion 14 of the driven side yoke 13.

  The retainer 53 is formed of an iron-based metal in an L-shaped cross section, and is provided with an annular portion 53a that is press-fitted and fixed to the outer peripheral surface of the small-diameter annular portion 7c of the casing 7, and an outer end portion of the annular portion 53a on the vehicle body front side. It is comprised from the flange part 53b extended toward the direction.

  The annular seal portion 54 is formed of, for example, resin, is fixed to one side surface 53c of the retainer 53, and is in contact with the back surface portion 14d of the small diameter step portion 14 of the driven side yoke 13.

  That is, the annular seal portion 54 shields the gap between the one side surface 53c of the flange portion 53b of the retainer 53 and the back surface portion 14d of the small-diameter step portion 14 of the driven side yoke 13, and the driven side yoke. 13 is rotated, and an increase in frictional resistance when the back surface portion 14d of the small diameter step portion 14 of the driven side yoke 13 slides on the other side surface of the annular seal portion 54 can be reduced.

  Accordingly, the annular seal portion 54 is prevented from being deteriorated in sealing performance, and the small diameter of the driven side yoke 13 is prevented by preventing entry of muddy water or the like into the outer peripheral surface 14b of the small diameter step portion 14 of the driven side yoke 13. Generation | occurrence | production of the rust of the outer peripheral surface 14b of the step part 14 can be prevented.

  In the fourteenth to eighteenth embodiments, grease G is filled in a plurality of space portions 39 formed between the sealing members 37, 37 of the sliding seal members 36, 36 and the seal portions 38, 38. By filling the space 39b not filled with the grease G, the waterproof property is further improved.

  The present invention is not limited to the configuration of the previous embodiment. For example, each of the cylindrical antirust members 34 and 33 is formed of another synthetic resin material or a plated metal member. It is also possible to do.

  The first and second dust covers 27 and 28 may be formed of a polyacetal resin material or other synthetic resin material, or may be formed of a plated metal member.

  In addition, the retainer 53 can be formed of resin, or the retainer 53 and the annular seal portion 54 can be integrally formed.

  Further, the annular seal portion 54 can be formed of an elastic member.

  Further, by polishing the opposing surfaces of the cylindrical anticorrosive members 34, 33 facing the side surfaces 23c, 23d of the inner race 23 of the bent portions 34b, 33b, for example, the friction of the opposing surfaces It is also possible to reduce the coefficient.

  Further, for example, each one side surface of the first and second dust covers 27 and 28 in the sixth to ninth embodiments facing the both side surfaces 23c and 23d of the inner race 23 of the bent portions 27e and 28e is polished. It is possible to reduce the coefficient of friction of the facing surface by processing.

  Furthermore, the present invention can be applied to a support device for a rotating shaft other than a support device for a propeller shaft of a vehicle.

It is a side view which shows a partial cross section of the propeller shaft provided for the first embodiment of the present invention. It is a front view of the support device of this embodiment. It is a principal part enlarged view of this embodiment. BRIEF DESCRIPTION OF THE DRAWINGS (a) is a general view of the cylindrical rustproof member provided for the first embodiment of the present invention. (B) is AA sectional view taken on the line of the cylindrical rustproof member provided for the first embodiment of the present invention. It is a side view which shows a partial cross section and shows the propeller shaft used for the 2nd Embodiment of this invention. It is a principal part enlarged view of 2nd Embodiment. It is a side view which shows the propeller shaft provided for the 3rd Embodiment of this invention in a partial cross section. It is a principal part enlarged view of 3rd Embodiment. It is a side view which shows a partial cross section and shows the propeller shaft used for the 4th Embodiment of this invention. It is a principal part enlarged view of 4th Embodiment. It is a principal part enlarged view of the 5th Embodiment of this invention. It is a side view which shows a partial cross section of the propeller shaft used for the 6th Embodiment of this invention. It is a principal part enlarged view of 6th Embodiment. It is a side view which shows a partial cross section of the propeller shaft used for the 7th Embodiment of this invention. It is a principal part enlarged view of 7th Embodiment. It is a side view which shows the propeller shaft provided for the 8th Embodiment of this invention in partial cross section. It is a principal part enlarged view of 8th Embodiment. It is a side view which shows a partial cross section of the propeller shaft provided for the ninth embodiment of the present invention. It is a principal part enlarged view of 9th Embodiment. It is a side view which shows the propeller shaft provided for the 10th Embodiment of this invention in partial cross section. It is a principal part enlarged view of 10th Embodiment. It is a side view which shows a partial cross section of the propeller shaft used for the eleventh embodiment of the present invention. It is a principal part enlarged view of 11th Embodiment. It is a principal part enlarged view of 12th Embodiment. It is a side view which shows the propeller shaft provided for the 13th Embodiment of this invention in partial cross section. It is a principal part enlarged view of 13th Embodiment. It is a side view which shows the propeller shaft provided for the 14th Embodiment of this invention in partial cross section. It is a principal part enlarged view of 14th Embodiment. It is a side view which shows the propeller shaft used for the 15th Embodiment of this invention in a partial cross section. It is a principal part enlarged view of 15th Embodiment. It is a side view which shows a partial cross section of the propeller shaft provided for the sixteenth embodiment of the present invention. It is a principal part enlarged view of 16th Embodiment. It is a side view which shows a partial cross section of the propeller shaft used in the seventeenth embodiment of the present invention. It is a principal part enlarged view of 17th Embodiment. It is a side view which shows the propeller shaft provided for the 18th Embodiment of this invention in partial cross section. It is a principal part enlarged view of 18th Embodiment. It is a side view which shows a partial cross section of the propeller shaft used in the nineteenth embodiment of the present invention. It is a principal part enlarged view of 19th Embodiment. It is a side view which shows the propeller shaft provided for 20th Embodiment of this invention in a partial cross section. It is a front view of the support apparatus of 20th Embodiment. It is a principal part enlarged view of 20th Embodiment. It is a side view which shows a partial cross section of the propeller shaft used for the 21st embodiment of the present invention. It is a principal part enlarged view of 21st Embodiment. It is a side view which shows the propeller shaft provided for the 22nd Embodiment of this invention in partial cross section. It is a principal part enlarged view of 22nd Embodiment. It is a side view which shows the propeller shaft provided for the 23rd Embodiment of this invention in partial cross section. It is a principal part enlarged view of 23rd Embodiment. It is a side view which partially shows and shows the propeller shaft provided for the 24th Embodiment of this invention. It is a principal part enlarged view of 24th Embodiment. It is action | operation explanatory drawing of the shielding part of 24th Embodiment. It is a side view which partially shows and shows the propeller shaft provided for the 25th Embodiment of this invention. It is a principal part enlarged view of 25th Embodiment. It is action | operation explanatory drawing of the shield of 25th Embodiment. It is a side view which partially shows and shows the propeller shaft provided for the 26th Embodiment of this invention. It is a principal part enlarged view of 26th Embodiment.

Explanation of symbols

1 ... Drive shaft (first shaft)
2 ... driven shaft (second shaft)
3. Cardan joint (joint part)
4 ... support device 5 ... elastic member 6 ... mounting bracket (annular member)
7: Casing (support member)
7d ... Inner peripheral surface 11a ... Large diameter shaft (shaft)
11b ... Medium diameter shaft (shaft)
11c ... outer peripheral surface 11d ... side end surface 14 ... small diameter step (shaft)
14a ... Small diameter end portion 14b ... Outer peripheral surface 14c ... Small diameter flat surface portion 14e ... Side end surface 21, 20 ... Annular seal member 21a, 20a ... Inner peripheral surface 22 ... Radial ball bearing (bearing)
34, 33 ... cylindrical rust prevention member (rust prevention part)

Claims (6)

An annular member attached to the floor member of the vehicle body;
An elastic member fixed inside the annular member;
A support member that rotatably supports the propeller shaft via a bearing inside the elastic member;
A propeller shaft support device comprising: an annular seal member disposed at least on one side of the bearing in the axial direction and in contact with an outer peripheral surface of the shaft portion of the propeller shaft so as to be able to rotate and slide;
Forming a rust preventive portion on the outer peripheral surface of the shaft portion with which the annular seal member abuts, and forming the rust preventive portion by a cylindrical rust preventive member fitted to the outer peripheral surface of the shaft portion;
The cylindrical rust preventive member is formed of a stainless steel material, and at one end of the cylindrical rust preventive member, an engagement portion that engages with the shaft portion is formed,
The engaging portion is formed by a bent portion in which one end portion of the cylindrical rust preventive member is bent inward, and the bent portion is opposed to the side end surface of the shaft portion and the side end surface. A propeller shaft support device, wherein the propeller shaft support device is disposed in a pinched state between one side surface of the bearing . The propeller shaft support device according to claim 1 , wherein a protruding portion is formed at the other end portion of the cylindrical antirust member . The propeller shaft support device according to claim 2 , wherein the protruding portion is formed by bending the other end portion of the cylindrical antirust member outward in the radial direction . The rust preventive portion is formed by a dust cover that is disposed at least on one side of the bearing in the axial direction and whose inner peripheral surface is in contact with the outer peripheral surface of the shaft portion of the propeller shaft. support apparatus of the propeller shaft according to 1. A propeller shaft support device for supporting a propeller shaft for transmitting a driving force from a drive source to a final reduction gear on a vehicle body,
An annular member fixed to the floor member of the vehicle body;
An elastic member fixed inside the annular member;
A support member that rotatably supports the propeller shaft via a radial ball bearing inside the elastic member;
An annular seal member that is disposed at least on one side in the axial direction of the radial ball bearing and has a seal portion that abuts the outer peripheral surface of the shaft portion of the propeller shaft on the inner periphery so as to be slidably rotatable;
A rust preventive portion is formed on an outer periphery of the shaft portion, the annular seal member is disposed at both sides in the axial direction of the radial ball bearing with a predetermined interval, and the rust preventive portion is disposed on the shaft of the radial ball bearing. On both sides of the direction,
While forming the rust prevention portion by a cylindrical rust prevention member fitted to the outer periphery of the shaft portion,
The cylindrical rust preventive member is formed of a stainless steel material, and at one end of the cylindrical rust preventive member, an engagement portion that engages with the shaft portion is formed,
The engaging portion is formed by a bent portion in which one end portion of the cylindrical rust preventive member is bent inward, and the bent portion is opposed to the side end surface of the shaft portion and the side end surface. A propeller shaft support device, wherein the propeller shaft support device is disposed in a pinched state with one side surface of the radial ball bearing . The propeller shaft support device according to claim 5, wherein a friction coefficient of at least the bent portion of the cylindrical rust preventive member is set to be lower than that of one side surface of the radial ball bearing .

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