JP4804493B2 - Spring seat rubber - Google Patents

Description

  The present invention relates to a spring seat rubber, and in particular, even when a phase of a recess for receiving a head of a fastening bolt and a phase of a starting end of a coil spring coincide with each other, it is possible to suppress a crack from occurring and breaking. The present invention relates to a spring seat rubber that can be used.

  The suspension mechanism suspends the wheel so that it can swing in the vertical direction with respect to the body frame by connecting the upper end of the shock absorber with the lower end connected to the wheel side to the body frame side via the mounting device. The spring seat rubber is interposed between the upper end portion of the coil spring fitted on the shock absorber and the receiving seat (flange portion) of the mount device.

  Thus, vibration transmitted from the wheel side to the vehicle body frame side via the shock absorber is reduced by the mounting device, and vibration transmitted from the wheel side to the vehicle body frame side via the coil spring is reduced by the spring seat rubber. Can do.

The mounting device includes a plurality of fastening bolts that are fastened to the vehicle body frame. The head of the fastening bolt protrudes from the lower surface of the receiving seat, but the upper surface (contacting surface) of the spring seat rubber. Has a plurality of recesses, and the recesses are configured to receive the heads of the fastening bolts. Thereby, the upper surface of a spring seat rubber can be made to contact | abut to the lower surface of a seat equally (patent document 1).
JP 2001-140964 (paragraph [0019], FIG. 1, etc.)

  However, in the above-described conventional spring seat rubber, since the recess for receiving the head of the fastening bolt is provided on the upper surface, the phase of this recess (particularly, the side wall of the recess) and the phase of the start end of the coil spring If they match, there is a problem that a crack occurs and breaks.

  That is, when the phase of the start end of the coil spring coincides with the phase of the side wall of the recess, two parallel and opposite forces with the side wall of the recess as a boundary (one force is the start end of the coil spring seats the spring seat rubber). The force that pushes the surface, the other force is the reaction force when the head of the fastening bolt supports the recess of the spring seat rubber (see Fig. 7), and the spring seat rubber is sheared, causing breakage Invite.

  On the other hand, in the process of assembling the suspension mechanism, it can be considered that the phase of the recess of the spring seat rubber is shifted from the phase of the start end of the coil spring. However, in this case, not only the assembly cost increases as the number of man-hours increases, but also breakage can be avoided when the coil springs are displaced in the rotational direction during running and the phases match. Can not.

  The present invention has been made to solve the above-described problems. Even when the phase of the recess for receiving the head portion of the fastening bolt and the phase of the starting end of the coil spring coincide with each other, a crack occurs and the fracture occurs. It aims at providing the spring seat rubber which can suppress doing.

  In order to achieve this object, the spring seat rubber according to claim 1 is composed of a rubber elastic body and is used by being interposed between the flange portion of the mounting device and the end portion of the coil spring. The mounting device is fastened to the vehicle body frame side, and the mounting device is fastened to the vehicle body frame side. A bolt is provided, and a head portion of the fastening bolt protrudes from the flange portion, and the main body portion and the overhang portion are located on one end side in the axial direction and are in contact with the flange portion of the mount device. A contact surface, a pressure receiving surface positioned on the other end side in the axial direction and facing the contact surface and receiving an end of the coil spring; and a head portion of the fastening bolt that is recessed in the contact surface. Accept A recess, and the phase of the receiving recess is matched with the phase of the overhanging portion, and the amount of the overhanging portion of the overhanging portion from the main body portion decreases as the distance from the receiving recess is increased. ing.

  The spring seat rubber according to claim 2 is the spring seat rubber according to claim 1, wherein the mount device includes a cylindrical inner fitting portion provided continuously to the flange portion, and the inner fitting portion is the main body. The main body portion includes an inner concave portion that is recessed on the inner peripheral side, and the phase of the inner concave portion is matched with the phase of the overhang portion, A width dimension of the inner concave portion is larger than a width dimension of the receiving concave portion and smaller than a width dimension of the overhanging portion.

  The spring seat rubber according to claim 3 is the spring seat rubber according to claim 2, wherein the spring seat rubber is annular when viewed in the axial direction and has an outer diameter smaller than that of the main body, and is continuously provided on the pressure receiving surface side of the main body. The fitting cylinder part is fitted with an inner fitting part of the mounting device on the inner peripheral side, and the inner concave part is opened on the contact surface side of the main body part. The pressure-receiving surface side of the main body is sealed by the fitting tube portion.

  According to the spring seat rubber according to claim 1, the flange portion of the mounting device includes a main body portion that is annular in an axial direction and a projecting portion that is formed to project radially outward from the outer peripheral side of the main body portion. And the end portion of the coil spring are abutted against the flange portion of the mounting device and the end portion of the coil spring is received by the pressure receiving surface. .

  In this case, since the receiving recess is recessed in the contact surface, the contact surface can be uniformly contacted with the flange portion of the mounting device by receiving the head of the fastening bolt in the receiving recess. it can. When the coil spring is compressed by the relative movement between the wheel and the vehicle body frame, the main body is clamped between the flange portion of the mount device and the end of the coil spring.

  Here, according to the present invention, the phase of the receiving recess is matched with the phase of the overhanging portion, that is, the overhanging portion is formed in the vicinity where the receiving recess is recessed, Therefore, the volume of the part that receives the end of the coil spring can be increased to ensure rigidity (reducing strain). Therefore, even if the phase of the receiving recess (particularly the side wall of the receiving recess) matches the phase of the start end of the coil spring, there is an effect that it is possible to suppress the occurrence of a crack and the breakage.

  Furthermore, in the present invention, since the amount of protrusion of the overhanging portion from the main body portion becomes smaller as the distance from the receiving recess is increased, the phase of the receiving recess (particularly the side wall of the receiving recess) and the phase of the start end of the coil spring are configured. Can be made uniform along the coil spring, the strain distribution of the main body pressed by the end of the coil spring.

  That is, the pressure receiving stress that the main body receives from the end of the coil spring becomes maximum at the start of the coil spring, and gradually decreases with distance from the start along the coil spring. If it is constant (in the direction along the coil spring), the strain distribution of the main body pressed against the end of the coil spring becomes non-uniform. For this reason, the entire main body cannot be deformed, and there is no escape area at the portion pressed by the starting end of the coil spring.

  In contrast, by adopting the above-described configuration, the strain distribution of the main body pressed by the end of the coil spring can be made uniform along the coil spring, so that the entire main body is deformed. Can do. As a result, even when the phase of the side wall of the receiving recess coincides with the phase of the start end of the coil spring, a relief area of the portion pressed by the start end of the coil spring is secured, and the pressure receiving stress is concentrated on a part of the main body. Can be suppressed. As a result, there is an effect that it is possible to suppress breakage due to generation of cracks.

  Further, according to the present invention, not only the main body portion but also the overhanging portion has a contact surface that comes into contact with the flange portion of the mounting device, and accordingly, a pressure receiving area can be secured. Thereby, when pressed by the end portion of the coil spring, the pressure receiving stress can be dispersed, and as a result, there is an effect that it is possible to suppress breakage due to generation of cracks.

  According to the spring seat rubber of the second aspect, in addition to the effect produced by the spring seat rubber of the first aspect, the inner fitting portion of the mounting device is configured to be fitted to the inner peripheral side of the main body portion. When the main body is sandwiched between the flange portion of the device and the end of the coil spring, the inner fitting portion of the mounting device receives the inner peripheral side of the main body portion, so that the main body portion is excessively deformed. (Generation of strain) can be suppressed and durability can be improved.

  In this case, according to the present invention, the main body portion is provided with the inner concave portion that is recessed on the inner peripheral side, and the phase of the inner concave portion matches the phase of the overhanging portion. Even if the inner peripheral side of the portion is received (restrained) by the inner fitting portion of the mounting device, if the phase of the side wall of the receiving recess matches the phase of the start end of the coil spring, It is possible to secure the escape area of the portion pressed by the start end by the inner concave portion and to prevent the pressure receiving stress from concentrating on a part of the main body portion. As a result, there is an effect that it is possible to suppress breakage due to generation of cracks.

  Here, according to the present invention, since the width of the inner recess is configured to be larger than the width of the receiving recess, when the phase of the side wall of the receiving recess matches the phase of the start end of the coil spring, The part pressed by the starting end of the coil spring can be easily released to the inner concave portion, and the pressure receiving stress can be prevented from concentrating on a part of the main body. As a result, there is an effect that it is possible to suppress breakage due to generation of cracks.

  On the other hand, according to the present invention, since the width dimension of the inner recess is made smaller than the width dimension of the overhang, even if the phase of the side wall of the receiving recess matches the phase of the start end of the coil spring, There is an effect that the strain distribution of the main body pressed by the end of the spring can be made uniform along the coil spring, and the breakage associated with the occurrence of a crack can be suppressed.

  That is, when the width dimension of the inner concave portion is larger than the width dimension of the overhanging portion, not only the portion pressed to the starting end of the coil spring but also the entire portion in the vicinity thereof escapes to the inner concave portion side. As described above, it becomes impossible to obtain the effect (uniform strain distribution) by the structure that changes the amount of overhang of the overhang portion.

  On the other hand, by making the width dimension of the inner recess smaller than the width dimension of the overhanging portion, the portion pressed against the starting end of the coil spring is released to the inner recess, and the portion in the vicinity thereof is the inner fitting portion of the mount device. It is possible to exhibit the effect of uniform strain distribution by the overhang portion. As a result, it is possible to suppress the pressure receiving stress from concentrating on a part of the main body. As a result, it is possible to suppress breakage associated with the generation of cracks.

  According to the spring seat rubber of the third aspect, in addition to the effect produced by the spring seat rubber of the second aspect, the fitting seat includes the fitting cylinder portion into which the inner fitting portion of the mounting device is fitted, Since it is configured to close the opening of the inner recess on the pressure receiving surface side of the main body portion by connecting to the pressure receiving surface side of the main body portion, the main body portion is between the flange portion of the mounting device and the end portion of the coil spring. There is an effect that it is possible to easily deform the main body part evenly in the thickness direction by suppressing the main body part from being deformed in a state where the main body part is tilted. As a result, it is possible to suppress the pressure stress from concentrating on a part of the main body, and to suppress the breakage associated with the occurrence of a crack.

  That is, in a configuration in which the fitting cylinder portion is not provided and the inner concave portion is opened on both sides of the contact surface and the pressure receiving surface, the main body portion is pinched between the flange portion of the mounting device and the end portion of the coil spring. In this case, the pressure-receiving surface side in the vicinity of the inner concave portion of the main body portion is easily displaced to the inner fitting portion side of the mounting device, so that the main body portion is deformed in an inclined state, and the pressure-receiving stress is concentrated on a part of the main body portion. In addition, breakage associated with the generation of cracks is caused.

  On the other hand, according to the present invention, by opening the inner concave portion on the contact surface side of the main body portion, the effect of facilitating escape of the portion pressed at the starting end of the coil spring to the inner concave portion as described above is ensured. On the other hand, when the main body is clamped between the flange portion of the mounting device and the end of the coil spring by closing the opening of the inner concave portion with the fitting cylinder portion on the pressure receiving surface side of the main body portion The displacement of the pressure receiving surface side in the vicinity of the inner concave portion of the main body portion toward the inner fitting portion side of the mount device can be received and suppressed by the fitting cylinder portion.

  As a result, the main body can be prevented from being deformed in a tilted state, and the main body can be easily deformed uniformly in the thickness direction. Thus, it is possible to suppress breakage associated with the occurrence of cracks.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the accompanying drawings. FIG. 1 is a partial cross-sectional view of a suspension mechanism 100 assembled with a spring seat rubber 1 according to an embodiment of the present invention. In FIG. 1, the illustration of the shock absorber attached to the collar 23 and the illustration of a part of the coil spring 3 are omitted for simplification of the drawing. The spring seat rubber 1 is illustrated as being deformed by a strut mount 2 and a coil spring 3.

  First, the configuration of the suspension mechanism 100 will be described with reference to FIG. The suspension mechanism 100 is a mechanism for maintaining the stability of the vehicle body by absorbing the displacement caused by the relative movement between the wheel (not shown) and the vehicle body (not shown). As shown in FIG. The seat rubber 1, the strut mount 2, and the coil spring 3 are mainly provided.

  The spring seat rubber 1 is a member for reducing vibration transmitted from the wheel side to the vehicle body side via the coil spring 3, a flange portion 11 having an axis O and a substantially annular shape, and its flange The fitting cylinder part 10 comprised by the substantially cylindrical shape standingly provided from the lower end part (FIG. 1 lower end part) of the part 11 is provided. The fitting tube portion 10 and the flange portion 11 are integrally vulcanized from a rubber-like elastic body.

  As shown in FIG. 1, the flange portion 11 includes a coil contact surface 11 a configured as a flat surface coupled to the fitting tube portion 10, and a surface disposed to face the coil contact surface 11 a. A metal fitting contact surface 11b and an inner peripheral surface 11d which is an inner side surface. The detailed configuration of the flange portion 11 will be described later with reference to FIGS.

  The inner diameter shape of the flange portion 11 is a shape corresponding to the outer diameter shape of an inner fitting portion 21a (see FIG. 5) of the strut mount 2 described later. When the spring seat rubber 1 is moved from the inner fitting portion 21a side toward the flange portion 21b side with the axis O of the flange portion 11 aligned with the extension of the axis O of the inner fitting portion 21a, the spring The seat rubber 1 is fitted on the strut mount 2.

  Further, as shown in FIG. 1, an inner recess 12 is formed in the inner peripheral surface 11 d of the flange portion 11, and the inner recess 12 is coupled to a metal fitting contact surface 11 b described later and is on the ring 13 side. It is extended toward.

  Embedded in the fitting cylinder portion 10 is a ring 13 formed of a metal material and formed in a tapered cylindrical shape whose upper side (upper side in FIG. 1) has an enlarged diameter.

  Moreover, the inner side recessed part 12 recessedly provided in the flange part 11 is opened by the upper end side (FIG. 1 upper end side) and the lower end side (FIG. 1 lower end side) by the ring 13 and the fitting cylinder part 10. FIG. .

  As shown in FIG. 1, the strut mount 2 includes a mounting bracket 20 configured in a substantially cylindrical shape on which the spring seat rubber 1 is fitted, a collar 23 housed in the mounting bracket 20, and the collar 23. And an anti-vibration base 24 vulcanized and bonded to the inner peripheral surface of the mounting bracket 20 and mounting bolts 25 protruding from the mounting bracket 20.

  The mounting bracket 20 includes a base portion 21 configured in a substantially cylindrical shape, and an upper plate 22 disposed on an upper portion of the base portion 21 (upper portion in FIG. 1).

  The base portion 21 has an inner fitting portion 21a formed in a substantially cylindrical shape having an axis O, and from the upper end portion (upper side in FIG. 1) of the inner fitting portion 21a toward the radially outer side (outward in the left-right direction in FIG. 1). A ring-shaped flange portion 21b that protrudes, and a ring-shaped partition portion 21c that protrudes radially inward (inward in the left-right direction in FIG. 1) from the inner peripheral surface of the inner fitting portion 21a. 21a, the flange part 21b, and the partition part 21c are integrally molded from a metal material.

  The outer diameter of the flange portion 21 b of the base portion 21 is set to be larger than the inner diameter of the flange portion 11 of the spring seat rubber 1, and the outer diameter of the inner fitting portion 21 a of the base portion 21 is set to the flange portion 11 of the spring seat rubber 1. Larger than the inner diameter (the flange portion 11 is elastically deformed so that the coil contact surface 11d (see FIG. 3) of the flange portion 11 is in close contact with the inner fitting portion 21a of the base portion 21).

  Therefore, when the shaft center O of the fitting cylinder portion 10 is made to coincide with the extension of the shaft center O of the inner fitting portion 21a, the spring seat rubber 1 is moved from the inner fitting portion 21a side toward the flange portion 21b side. The metal member contact surface 11b of the flange portion 11 is brought into contact with the portion 21b so that the spring seat rubber 1 can be locked by the lower surface (the lower surface in FIG. 2) of the flange portion 21b and the coil contact surface 11d of the flange portion 11 is used. (See FIG. 3) is in close contact with the inner fitting portion 21 a of the base portion 21, so that the spring seat rubber 1 can be prevented from falling off the base portion 21.

  As shown in FIG. 1, the upper plate 22 has an axial center O and is configured in a ring-like flat plate shape when viewed from above (viewed from the upper side to the lower side in FIG. 1), and the mechanical clinch 26 is formed. It is made integral with the flange part 21b mentioned above. The configuration of the mechanical clinch 26 will be described later with reference to FIGS. 4 and 5.

  The collar 23 includes a collar tube portion 23a formed in a substantially cylindrical shape having an axis different from the shaft center O, and radially outward from the upper end portion (upper side in FIG. 1) of the collar tube portion 23a (outward in the left-right direction in FIG. 1). A collar flange portion 23b projecting toward the front is provided, and the collar tube portion 23a and the collar flange portion 23b are integrally formed from a metal material.

  The anti-vibration base 24 is vulcanized and molded from a rubber-like elastic body into a ring shape, and is disposed inside the inner fitting portion 21a and between the partition portion 21c and the upper plate 22, and is added to the collar flange portion 23b. Sulfur bonded.

  The mounting bolt 25 is a member for mounting the mounting bracket 20 on the vehicle body side, is inserted through the upper plate 22 and the flange portion 21b, and is non-rotatably engaged with the flange portion 21b by serration.

  As shown in FIG. 1, the coil spring 3 has an axis O and is helically formed from a metal wire, and has an inner diameter that is smaller than the outer diameter of the flange portion 11 and larger than the outer diameter of the fitting tube portion 10. is doing.

  For this reason, when the axial center O of the coil spring 3 is aligned with the axial center O of the fitting cylinder portion 10, the axial center O direction of the coil spring 3 (vertical direction in FIG. 1) on the coil contact surface 11 a of the flange portion 11. One of the pair of end portions 3a, which is the end portion of each, is abutted. The other side of the coil spring 3 is in contact with the wheel side.

  As described above, in the suspension mechanism 100, the mounting bracket 20 is attached to the vehicle body via the mounting bolt 25, and the collar 23 is attached to the mounting bracket 20 of the strut mount 2 via the vibration isolation base 24. . One end side of a shock absorber (not shown) with the other end side attached to the wheel side is attached to the collar 23. Further, the inner fitting portion 21 a of the mounting bracket 20 is fitted into the fitting cylinder portion 10 of the spring seat rubber 1, and the fitting contact surface 11 b of the spring seat rubber 1 contacts the flange portion 21 b of the mounting bracket 20. It is touched. One of the pair of end portions 3a of the coil spring 3 is in contact with the coil contact surface 11a of the spring seat rubber 1, and the other is in contact with the wheel side.

  The spring seat rubber 1 is held between the flange portion 21b of the mounting bracket 20 and the end portion 3a of the coil spring 3 and is pressed by a load from a vehicle body (not shown). As a result, the end 3a of the coil spring 3 deforms the spring seat rubber 1 and sinks the coil contact surface 11a of the spring seat rubber 1 toward the fitting contact surface 11b.

  On the other hand, the coil spring 3 is formed in a spiral shape from a metal wire, and an end surface 3b (FIG. 1), which is a cut surface of the metal wire, is disposed at an end portion 3a of the coil spring 3 in the axis O direction (vertical direction in FIG. 1). 6) is formed. Therefore, when the end portion 3a of the coil spring 3 sinks the coil contact surface 11a of the spring seat rubber 1 (see FIG. 7A), a shearing force is generated at the end surface 3b. As a result, a crack may occur starting from a portion on the coil contact surface 11a with which the end surface 3b is contacted, and the flange portion 11 may be broken.

  Further, by accommodating a part of the spring seat rubber 1 deformed in the space S that is a space formed between the inner concave portion 12 and the inner fitting portion 21a, the entire spring seat rubber 1 is uniformly deformed. Thus, it is possible to prevent a large shear force from being generated in the spring seat rubber 1 and improve the durability of the spring seat rubber 1.

  Next, with reference to FIG.2 and FIG.3, the detailed structure of the spring seat rubber 1 is demonstrated. 2 is a top view of the spring seat rubber 1, and FIG. 3 is a cross-sectional view of the spring seat rubber 1 taken along line III-III in FIG.

  As shown in FIGS. 2 and 3, the spring seat rubber 1 includes a fitting cylinder portion 10 formed in a substantially cylindrical shape having an axis O and an upper end portion (upper side in FIG. 1) of the fitting cylinder portion 10. And a flange portion 11 protruding outward in the radial direction (outward in the left-right direction in FIG. 1). The fitting tube portion 10 and the flange portion 11 are integrally vulcanized from a rubber-like elastic body.

  As described above, the inner recess 12 is formed in the inner peripheral surface 11d of the flange portion 11, and the inner recess 12 extends from the metal fitting contact surface 11b toward the ring 13 as shown in FIG. It is extended.

  Further, the inner peripheral surface 11d includes an upper inner peripheral surface 11d1 that is a surface of the inner peripheral surface 11d on the metal fitting contact surface 11b side (upper side in FIG. 3) and a ring 13 side (lower side in FIG. 3) of the inner peripheral surface 11d. And a lower inner peripheral surface 11d2 that is a surface.

  As shown in FIGS. 2 and 3, the inner recess 12 includes a bottom surface 12a, a pair of wall surfaces 12b, and a connecting surface 12c.

  As shown in FIG. 3, the bottom surface 12 a is a curved surface coupled to the metal fitting contact surface 11 b and is curved in a direction along the axis O from the metal fitting contact surface 11 b disposed at a right angle to the shaft center O. It extends to the ring 13 side.

  The bottom surface 12a includes a lower bottom surface 12a2 that is a surface of the bottom surface 12a on the ring 13 side (lower side in FIG. 3), and an upper bottom surface 12a1 that is a surface of the bottom surface 12a on the metal fitting contact surface 11b side (upper side in FIG. 3). Yes.

  As shown in FIGS. 2 and 3, the pair of wall surfaces 12 b are configured as flat surfaces and are erected from both sides of the bottom surface 12 a in the circumferential direction of the spring seat rubber 1, and the pair of wall surfaces 12 b are parallel to each other. It is arranged. The connecting surface 12c is configured as a flat surface and is connected to each of the pair of wall surfaces 12b.

  As shown in FIG. 2, a curved surface 12f, which is a connecting surface between the bottom surface 12a and the wall surface 12b, and a curved surface 12g, which is a connecting surface between the wall surface 12b and the connecting surface 12c, are configured as curved surfaces. Therefore, concentration of force generated when the spring seat rubber 1 is deformed can be prevented and durability of the curved surface 12f and the curved surface 12g can be improved. As a result, the durability of the spring seat rubber 1 can be improved.

  Further, as shown in FIG. 3, the lower bottom surface 12a2 is configured such that a cross-sectional line cut by a plane including the axis O is parallel to a direction along the axis O (vertical direction in FIG. 3), and the lower inner peripheral surface 11d2 is configured to be closer to the axis O as the cross-sectional line cut by the plane including the axis O and the wall surface 12b is closer to the ring 13 side. Therefore, the closer to the ring 13 side, the deeper the inner recess 12 (the dimension in the left-right direction in FIG. 3) becomes deeper.

  Further, the upper bottom surface 12a1 is bent in a direction away from the axis O (the left direction in FIG. 3) as the cross-sectional line including the axis O moves toward the metal fitting contact surface 11b, and the curvature of the cross-sectional line becomes a radius R1. Is set.

  Further, as shown in FIG. 3, the upper inner peripheral surface 11d1 is separated from the axis O as the cross-sectional line cut by the plane including the axis O and the wall surface 12b moves toward the metal fitting contact surface 11b (FIG. 3). (The left-right outward direction), and the curvature of the cross-sectional line is set to the radius R2.

  The upper inner peripheral surface 11d1 and the upper bottom surface 12a1 are connected to a position at the same distance from the axis O on the metal fitting contact surface 11b in the radial direction of the circle centered on the axis O. Further, the radius R2 of the cross section line of the upper inner peripheral surface 11d1 is set to a value larger than the radius R1 of the cross section line of the upper bottom surface 12a1 (R2> R1). Therefore, the cross-sectional line of the upper inner peripheral surface 11d1 is closer to the axis O side than the cross-sectional line of the upper bottom surface 12a1 as it goes to the ring 13 side.

  Therefore, the shape of the wall surface 12b is a triangular shape when viewed from the front (viewed in the vertical direction in FIG. 3), and the tip of the acute-angled portion of the triangular shape is bent outside the spring seat rubber 1 (the left and right direction outside in FIG. 3). The That is, the depth dimension T2 on the lower surface side (lower side in FIG. 3) is larger than the depth dimension T1 on the upper surface side (upper side in FIG. 3) of the inner recess 12 (T2> T1). Further, as shown in FIG. 2, the dimension value of the wall surfaces 12b facing each other is set to the width dimension W2.

  As shown in FIG. 2, the flange portion 11 includes a plurality of projecting portions 14 that project from the virtual circle R that is a virtual circle having a radius R1 centering on the axis O to the outside in the radial direction of the axis O ( In the present embodiment, there are three), and the plurality of projecting portions 14 are arranged at equal intervals in the circumferential direction around the axis O (at intervals of 120 degrees at the central angle).

  As shown in FIG. 2, the overhanging portion 14 includes a pair of side surfaces 14a, a connecting surface 14b, and a pair of upper surfaces 14c.

  The side surface 14a is a flat surface along the extending direction of the axis O, and is in contact with the virtual circle R in a top view (viewed in the direction perpendicular to the paper surface of FIG. 2). The connecting surface 14b is a curved surface coupled between the pair of side surfaces 14a.

  That is, the overhanging portion 14 is surrounded by the virtual circle R, the side surface 14a, and the connecting surface 14b in the top view (viewed in the vertical direction in FIG. 2). The isosceles triangle shape has a curved shape that is recessed toward the apex side where the bases of the isosceles triangles face each other.

  Therefore, the radial dimension value of the virtual circle R of the projecting portion 14 (corresponding to the “projection amount” described in claim 1) as it is separated from the bolt head recess 16 described later in the circumferential direction of the virtual circle R. Get smaller.

  The upper surface 14c is a surface that is disposed on both sides of a bolt head recess 16 to be described later and that is disposed outside the virtual circle R. Note that the width in the circumferential direction of the virtual circle R of the overhang portion 14 is set to a width dimension W3. From the width dimension W2 that is an opposing interval of the wall surface 12b described later and the width dimension W1 that is an opposing interval of the wall surface 16b. It is set to a large value.

  As shown in FIG. 2, a plurality (three in this embodiment) of concave portions 15 for mechanical clinch and a plurality (three in this embodiment) of bolt heads are provided on the metal fitting contact surface 11b of the flange portion 11. A concave portion 16 is provided.

  As shown in FIGS. 2 and 3, a plurality (three in the present embodiment) of bolt head recesses 16 have an axis S <b> 1 and are equally spaced in the circumferential direction of the virtual circle R (120 at the central angle). Are arranged so that the axis S1 of the bolt head recess 16 is positioned on the circumference of the virtual circle R.

  Similarly, a plurality (three in the present embodiment) of the mechanical clinch recesses 15 have an axial center S2 and are equidistant in the circumferential direction of the virtual circle R (120 degrees apart at the central angle). In addition, the axial center S2 of the mechanical clinch recess 15 is disposed so as to be located on the circumference having a radius R2 from the axial center O to the axial center S2 of the mechanical clinch recess 15. The bolt head recesses 16 and the mechanical clinch recesses 15 are alternately arranged (60 degrees apart at the center angle).

  As shown in FIGS. 2 and 3, the mechanical clinch recess 15 is configured to have a shape in which one arc side (outside of the flange portion 11) of an ellipse when viewed from above (viewed in the vertical direction in FIG. 2) is opened. , A bottom surface 15a, a pair of wall surfaces 15b, and a connecting surface 15c.

  The bottom surface 15a is configured as a flat surface and is disposed orthogonal to the axis O, and the pair of wall surfaces 15b are configured as flat surfaces and both sides of the bottom surface 15a in the circumferential direction of the spring seat rubber 1. Each is established from.

  Further, as shown in FIG. 2, the pair of wall surfaces 15b are arranged in parallel to each other and are connected to each other by a connecting surface 15c, and the connecting surface 15c is configured as a curved surface with the axis S2 as the center. Yes. Further, the standing height (the vertical dimension value in FIG. 3) of the wall surface 15b and the connecting surface 15c is set to the height dimension H3.

  Further, as shown in FIG. 3, a curved surface 15d that is a connecting surface between the bottom surface 15a and the wall surface 15b and a curved surface 15e that is a connecting surface between the bottom surface 15a and the connecting surface 15c are configured as curved surfaces.

  Therefore, when the spring seat rubber 1 is deformed, it is possible to prevent the force from being concentrated on one place and to improve the durability of the curved surface 15d and the curved surface 15e. As a result, the durability of the spring seat rubber 1 can be improved.

  As shown in FIGS. 2 and 3, the bolt head recess 16 is configured to have a shape in which one arc side (outside of the flange portion 11) of the ellipse in the top view (viewed in the vertical direction in FIG. 2) is opened. , A bottom surface 16a, a pair of wall surfaces 16b, and a connecting surface 16c.

  As shown in FIG. 3, the bottom surface 16 a is configured as a flat surface and is disposed orthogonal to the axis O. As shown in FIG. 2, the pair of wall surfaces 16 b are configured as flat surfaces and are erected from both sides of the bottom surface 16 a in the circumferential direction of the spring seat rubber 1.

  Further, as shown in FIG. 3, the pair of wall surfaces 16b are arranged in parallel to each other, and the pair of wall surfaces 16b are connected by a connecting surface 16c. The connecting surface 16c is erected from the bottom surface 16a and is configured as a curved surface centered on the axis S1. Further, the standing height (the vertical dimension value in FIG. 3) of the wall surface 16b and the connecting surface 16c is set to the height dimension H2.

  Further, as shown in FIG. 3, a curved surface 16d that is a connecting surface between the bottom surface 16a and the wall surface 16b and a curved surface 16e that is a connecting surface between the bottom surface 16a and the connecting surface 16c are configured as curved surfaces. Therefore, when the spring seat rubber 1 is deformed, it is possible to prevent the force from concentrating on one place and to improve the durability of the curved surface 16d and the curved surface 16e. As a result, the durability of the spring seat rubber 1 can be improved.

  Also, as shown in FIG. 3, the bottom surface 16a of the bolt head recess 16 is disposed on the ring 13 side (lower side in FIG. 3) by a height dimension H1 from the bottom surface 15a of the mechanical clinch recess 15.

  Here, when the spring seat rubber 1 is combined with the strut mount 2 (see FIG. 1), the bolt head 25a (see FIG. 1) is brought into contact with the bottom surface 16a of the bolt head recess 16, and the bottom surface 16a is on the ring 13 side (see FIG. 1). 3 lower side).

  Therefore, the bottom surface 15a of the mechanical clinch recess 15 is pulled toward the ring 13 (lower side in FIG. 3) by deformation of the bottom surface 16a of the bolt head recess 16. Therefore, a tensile force is generated at a portion between the bottom surface 16 a of the bolt head recess 16 and the bottom surface 15 a of the mechanical clinch recess 15.

  As a result, when the coil spring 3 (see FIG. 1) presses the spring seat rubber 1, the balance between the compressive force and the pulling force acting on the spring seat rubber 1 is maintained, and the spring seat rubber 1 is locally localized. Therefore, the durability of the spring seat rubber 1 can be improved.

  As shown in FIG. 2, the overhanging portion 14 is disposed on an extension line of the pair of wall surfaces 12 b of the inner concave portion 12 in a top view (viewed in a direction perpendicular to the paper surface in FIG. 2). That is, since the overhang | projection part 14 is arrange | positioned in the outer periphery of the flange part 11, the cross-sectional area of the spring seat rubber 1 cut off by the plane containing the axial center O and the wall surface 12b increases.

  Therefore, since the force acting on the spring seat rubber 1 can be dispersed and received by the amount of the increased cross-sectional area, the strength of the spring seat rubber 1 is improved and the durability of the spring seat rubber 1 can be improved. it can.

  As shown in FIG. 2, the facing distance between the mutually facing wall surfaces 16b of the bolt head recess 16 is set to the width dimension W1, and the width dimension W1 is the facing distance between the pair of wall surfaces 12b of the inner recess 12 described above. A value smaller than the width dimension W2 is set (W1 <W2).

  Further, the bolt head recess 16 is disposed between the extension lines of the pair of wall surfaces 12b, and a part of the inner recess 12 is used for the bolt head in the radial direction of the virtual circle R centering on the axis O. It overlaps with the entire recess 16.

  For example, the width dimension W1 is set to a value larger than the width dimension W2 that is the interval between the pair of wall surfaces 12b described above (W1> W2), and in the circumferential direction of the virtual circle R centering on the axis O, the inner concave portion When the entire 12 overlaps the bolt head recess 16, the bolt head recess 16 is always included on the plane including the axis O and the wall surface 12b.

  Since the bolt head concave portion 16 has a concave shape, the cross-sectional area of the flange portion 11 including the axis O and the wall surface 12b decreases by the cross-sectional integral of the bolt head concave portion 16.

  Accordingly, the area of the cross section of the flange portion 11 including the axis O and the wall surface 12b is reduced, and the force acting on the flange portion 11 is difficult to be dispersed. As a result, in the cross section of the flange portion 11 and including the axis O and the wall surface 12b, it is difficult to improve the strength of the flange portion 11 and to improve the durability of the spring seat rubber 1.

  Here, in the present invention, the width dimension W1 is set to a value smaller than the width dimension W2 (W1 <W2), and the bolt head recess 16 as a whole in the circumferential direction of the virtual circle R centering on the axis O. Overlaps the inner recess 12.

  That is, the bolt head recess 16 is not disposed on the cross section including the axis O and the wall surface 12b. Therefore, it is possible to prevent the cross-sectional area of the flange portion 11 including the axis O and the wall surface 12b from decreasing by the cross-sectional integral of the bolt head recess 16.

  As a result, a decrease in strength of the flange portion 11 in the cross section of the flange portion 11 including the axis O and the wall surface 12b is prevented, and the durability of the spring seat rubber 1 can be ensured.

  As shown in FIG. 3, the taper angle A <b> 1 with respect to the axis O of the inner peripheral surface 13 a that is the inner surface of the ring 13 is the taper angle with respect to the axis O of the inner peripheral surface 10 a formed inside the ring 13. It is set to be equivalent to A2.

  That is, the cross-sectional lines in the cross section including the axis O between the inner peripheral surface 10a and the inner peripheral surface 13a of the ring 13 are parallel to each other. Therefore, when a force is applied to the inner peripheral surface 10 a, the portion of the fitting cylinder portion 10 and the inner portion of the ring 13 is evenly pressed by the inner peripheral surface 13 a of the ring 13. As a result, it is possible to prevent a large force from being generated locally in the flange portion 11 and improve the durability of the fitting tube portion 10.

  Next, the structure of the strut mount 2 will be described with reference to FIGS. 4 and 5. 4 is a top view of the strut mount 2, and FIG. 5 is a cross-sectional view of the strut mount 2 taken along the line V-V in FIG.

  As shown in FIGS. 4 and 5, the strut mount 2 includes a mounting bracket 20 that has an axial center O and is configured in a substantially cylindrical shape on which the spring seat rubber 1 is fitted, and is housed in the mounting bracket 20. And a vibration isolating base 24 vulcanized and bonded to the collar 23 and the inner peripheral surface of the mounting bracket 20, and mounting bolts 25 protruding from the mounting bracket 20.

  The mounting bracket 20 includes a base portion 21 having an axis O and configured in a substantially cylindrical shape, and an upper plate 22 having an axis O disposed on an upper portion of the base portion 21 (upper part in FIG. 1). ing. Moreover, the base | substrate part 21 is provided with the internal fitting part 21a and the flange part 21b.

  As shown in FIGS. 4 and 5, the upper plate 22 and the flange portion 21 b of the base portion 21 are overlapped so that the axial centers O coincide with each other, and the upper surface side of the overlapped upper plate 22. A plurality (three in the present embodiment) of mounting bolts 25 having an axis S3 protrude from the (upper surface side in FIG. 5).

  As shown in FIG. 4, a plurality (three in the present embodiment) of the mounting bolts 25 are equidistant in the circumferential direction around the axis O (at intervals of 120 degrees at the center angle), and the axis is centered. The distance from O to the axis S3 of the mounting bolt 25 is arranged on a circumference having a radius R3.

  Similarly, a plurality (three in the present embodiment) of mechanical clinch 26 has an axis S4 and is equally spaced in the circumferential direction centered on the axis O (at an interval of 120 degrees at the center angle). The distance from the center O to the axis S4 of the mechanical clinch 26 is arranged on a circumference having a radius R4. The mounting bolts 25 and the mechanical clinch 26 are alternately arranged (60 degree intervals at the central angle).

  As shown in FIG. 5, the mounting bolt 25 is a member for mounting the mounting bracket 20 on the vehicle body side, and serrations (not shown) are formed on the outer peripheral surface of the mounting bolt 25.

  Similarly, serrations corresponding to the serrations formed on the mounting bolts 25 are also formed in the through holes (not shown) of the flange portion 21b. Therefore, the mounting bolt 25 is engaged with the flange portion 21b so as not to rotate.

  Therefore, when fastening the mounting bolt 25 to the vehicle body side, it is not necessary to fix the mounting bolt 25 with a jig, and the bolt head 25a need not have a shape corresponding to a fastening tool such as a driver. Therefore, the bolt head 25a can be formed in a circular flat plate shape when viewed from the front (viewed in the vertical direction in FIG. 4).

  The bolt head 25a is formed of a curved surface with a smooth connection between the outer peripheral surface and a circular surface when viewed from the front (viewed in the vertical direction in FIG. 4). Therefore, even when the bolt head 25a abuts against the bolt head recess 16 (see FIG. 3), a large force is prevented from being locally generated on the bottom surface 16a of the bolt head recess 16, and the durability of the bottom surface 16a is improved. The durability of the spring seat rubber 1 can be improved. The thickness of the bolt head 25a is set to a dimension value of the height dimension H5.

  Further, as shown in FIG. 5, the mechanical clinch 26 has two bar-shaped pins (not shown) pressed between the upper plate 22 and the flange portion 21b from both sides so that the upper plate 22 and the flange portion 21b are pressed. It is a part formed by depression. Therefore, on the lower surface side (lower surface side in FIG. 5) of the flange portion 21b, a mechanical clinch protrusion portion 26a is formed in which the sacrificial portion of the portion deformed by the depression is raised.

  The mechanical clinch protrusion 26a is formed by pressing the mounting bracket 20 and the flange portion 21b with a circular pin (not shown), so that the circular shape is transferred and viewed from below (viewed from below in FIG. 5). It is configured in a ring shape and is projected from the upper plate 22 side (upper side in FIG. 5) toward the mounting bracket 20 side (lower side in FIG. 5) with a dimension value of the height dimension H4.

  The height dimension H3 (see FIG. 3) of the mechanical clinch recess 15 described above is set to a value larger than four times the height dimension H4 of the mechanical clinch protrusion 26a (H4> H3 × 4).

  Therefore, even when the thickness (the vertical dimension value in FIG. 1) of the spring seat rubber 1 (see FIG. 1) is crushed due to aging, the mechanical clinch protrusion 26a contacts the mechanical clinch recess 15 (see FIG. 3). Can be prevented. As a result, the service life of the spring seat rubber 1 (see FIG. 1) can be extended.

  Alternatively, if the life of the spring seat rubber 1 is set constant, the rubber-like elastic body constituting the spring seat rubber 1 can be changed to a material with low cost. As a result, the product cost of the spring seat rubber 1 can be reduced.

  Further, the dimension value in the thickness direction (up and down direction in FIG. 5) between the upper plate 22 and the flange portion 21b, and the thickness dimension T3 of the part into which the mounting bolt 25 is press-fitted is the part where the mechanical clinch 26 is formed The dimension value is set to be larger than the thickness dimension T4 (T3> T4).

  Therefore, compared with the case where the mounting bolt 25 is press-fitted into the portion having the thickness dimension T4, a sufficient press-fitting allowance for the mounting bolt 25 can be ensured. Moreover, compared with the case where the mechanical clinch 26 is formed in the site | part of thickness dimension T3, the intensity | strength of the site | part in which the mechanical clinch 26 is formed can be made low, and formation of the mechanical clinch 26 can be made easy. Thus, the mounting bracket 20 and the upper plate 22 are integrated by a plurality of (three in this embodiment) mechanical clinch 26.

  Next, the positional relationship between the bolt head recess 16 of the spring seat rubber 1 and the bolt head 25a of the mounting bolt 25 will be described with reference to FIGS. FIG. 6 is a partial bottom view of the portion of the suspension mechanism 100 in which the bolt head recess 16 is disposed as viewed from the coil spring 3 side toward the strut mount 2 side, and the end surface 3b of the coil spring 3 is used for the bolt head. The state arrange | positioned on the back surface of the recessed part 16 is shown.

  In FIG. 6, the end 3 a of the coil spring 3 is hatched for easy understanding of the drawing.

  7A is a partial cross-sectional view of the suspension mechanism 100 taken along line VIIa-VIIa in FIG. 6, and FIG. 7B is a view before the coil spring 3 in FIG. 7A is pressed against the strut mount 2. FIG. FIG. 8 is a partial cross-sectional view of the suspension mechanism 100 showing this state, corresponding to FIG. FIG. 7C is a partial cross-sectional view of the suspension mechanism 100 taken along line VIIc-VIIc in FIG.

  As shown in FIG. 6, the spring seat rubber 1 and the strut mount 2 are overlapped with each other so that their axial centers O coincide with each other, and the axial center O1 extends from the axial center S1 of the connecting surface 16 c of the bolt head recess 16. And the radius R3 which is the distance from the axis S3 of the mounting bolt 25 to the axis O is the same distance (R1 = R3).

  Therefore, the circumferential position of the circle centered on the axis O between the spring seat rubber 1 and the strut mount 2 in the circumferential direction centered on the axis O (corresponding to the “phase” according to claim 1). .) (Hereinafter referred to as “arrangement angle”), the mounting bolt 25 of the strut mount 2 is accommodated in the bolt head recess 16 of the spring seat rubber 1.

  In addition, a plurality (three in the present embodiment) of bolt head recesses 16 and a plurality (three in the present embodiment) of mounting bolts 25 are provided in the circumferential direction of the mounting bracket 20 around the axis O. Are arranged at intervals of a predetermined angle (a central angle of 120 degrees).

  That is, when the spring seat rubber 1 and the strut mount 2 are overlapped, the arrangement is such that the arrangement angle of one bolt head recess 16 and the arrangement angle of one mounting bolt 25 are matched. Thus, a plurality (three in this embodiment) of bolt head recesses 16 and a plurality (three in this embodiment) of mounting bolts 25 can be overlapped with each other.

  Further, since the height dimension H5 of the bolt head 25a and the height dimension H2 of the wall surface 16b of the bolt head recess 16 are substantially the same, the bolt head 25a is received in the bolt head recess 16 and the coil spring 3 is received. The coil abutment surface 11a of the spring seat rubber 1 can be uniformly abutted against the flange portion 21b of the strut mount 2 by being pressed by.

  Since the spring seat rubber 1 is made of a rubber-like elastic body, even when the bottom surface 16a of the bolt head recess 16 is abutted against the bolt head 25a, the bottom surface 16a is the metal fitting contact surface 11b. By being deformed to the side, the coil contact surface 11 a of the spring seat rubber 1 can be uniformly contacted with the flange portion 21 b of the strut mount 2.

  In addition, in this case, since the bottom surface 16a of the bolt head recess 16 is also pressed by the coil spring 3 and the bolt head 25a, the spring seat rubber 1 can be deformed as a whole, and the flange portion 11 is locally Therefore, it is possible to prevent the spring seat rubber 1 from being damaged.

  As shown in FIG. 6, when the coil spring 3 is arranged on the spring seat rubber 1, the arrangement angle is not restricted in the circumferential direction of the coil spring 3, and the end surface of the coil spring 3 3b is arranged at an arbitrary position on the circumference of the spring seat rubber 1.

  Further, since the coil spring 3 is configured as a coil spring formed by winding a metal wire on a spiral, a portion of the end surface 3b of the coil spring 3 that contacts the spring seat rubber 1 is interrupted, and the coil spring 3 is not pressed. Consecutive and stepped.

  For this reason, when the coil spring 3 is disposed on the spring seat rubber 1 and the spring seat rubber 1 is pressed, the force acting on the spring seat rubber 1 greatly changes with the end surface 3b of the coil spring 3 as a boundary.

  Further, the arrangement angle of the coil spring 3 is not restricted, and the end surface 3b is disposed at an arbitrary position on the circumference of the spring seat rubber 1, so that the end surface 3b is disposed as shown in FIG. The angle may be between the bolt head recess 16 and the bolt head 25a in the bottom view (viewed in the vertical direction in FIG. 6).

  In this case, as shown in FIG. 7B, the coil spring 3 is brought into contact with the spring seat rubber 1, and a load is applied to the coil spring 3 as shown in FIG. Is buried in the spring seat rubber 1.

  Therefore, the compression force (force acting downward in FIG. 7A) acts on the coil spring 3 side (right side in FIG. 7A) with the end face 3b as a boundary, and the mounting bolt 25 side (FIG. 7B). On the left side, a restoring force (force acting in the upward direction in FIG. 7A) that opposes the compressive force acts. That is, a shearing force is generated in the spring seat rubber 1 with the end face 3b as a boundary.

  As shown in FIG. 7 (a), the thin-walled portion 11c, which is the portion of the flange portion 11 and the portion of the rear surface of the bolt head recess 16 and located on the coil contact surface 11a side, is used for the bolt head. The thickness (FIG. 7 (a) vertical dimension value) is reduced by the depth of the recess 16 (FIG. 7 (a) vertical dimension value), and the flange portion 11 of the spring seat rubber 1 is a coil spring. The thickness is the thinnest among the portions where 3 is in contact.

  For this reason, the thin portion 11c is a portion of the flange portion 11 where the strength against the shearing force is the lowest among the portions where the coil spring 3 is in contact. As a result, a crack may occur in the thin portion 11c due to a shearing force generated at the end surface 3b of the coil spring 3 and may be broken.

  For example, when the entire flange portion 11 is made thick in order to prevent the thin portion 11c from being broken, the dimensional value in the length direction of the suspension mechanism 100 is increased, and the degree of freedom of layout in an automobile is deteriorated. In addition, since the overall thickness is increased, the material cost of the spring seat rubber 1 increases.

  Here, in the present embodiment, as shown in FIGS. 6 and 7C, a plurality of (three in the present embodiment) overhanging portions 14 are formed on the outer periphery of the flange portion 11, and the flanges are formed. The bolt head recess 16 is formed on the metal fitting contact surface 11b which is the upper surface of the portion 11 (the surface on the paper surface vertical side in FIG. 5) and the upper surface 14c which is the upper surface of the overhang portion 14 (the surface on the paper surface in the vertical direction in FIG. Is recessed.

  That is, the spring seat rubber 1 is provided with an overhanging portion 14 in which a part of the bolt head concave portion 16 is provided on the radially outer side (upper side in FIG. 6) of the flange portion 11. The strength of the thin portion 11c can be improved without increasing the height (FIG. 7 (c) vertical dimension value). As a result, it is possible to prevent the thin-walled portion 11c from being cracked by a shearing force generated at the end surface 3b of the coil spring 3 and being broken.

  Further, the projecting portion 14 is formed in a substantially isosceles triangle shape in a top view (viewed in the vertical direction in FIG. 2), and has a curved shape in which the bottom sides of the isosceles triangles are recessed on the opposite vertex side. The radial dimension value of the imaginary circle R of the bulging portion 14 (corresponding to the “projection amount” described in claim 1) decreases as the distance from the imaginary circle R in the circumferential direction increases.

  Therefore, when the wall surface 16b of the bolt head recess 16 and the end surface 3b of the coil spring 3 are aligned or close to each other, the strain distribution of the flange portion 11 pressed by the end surface 3b of the coil spring 3 is expressed as the coil. It can be uniform along the spring 3.

  That is, the stress that the flange portion 11 receives from the end portion 3 a of the coil spring 3 (hereinafter referred to as “pressure receiving stress”) is maximized at the end surface 3 b of the coil spring 3, and as the distance from the end surface 3 b along the coil spring 3 increases. In order to gradually decrease, if the amount of protrusion of the protrusion 14 is constant in the circumferential direction of the virtual circle R (direction along the coil spring), the strain distribution of the flange portion 11 pressed against the end 3 a of the coil spring 3 is distributed. It is not uniform. For this reason, the entire flange portion 11 cannot be deformed, and there is no escape area at the portion pressed against the end surface 3 b of the coil spring 3.

  On the other hand, in the present embodiment, since the amount of overhanging portion 14 is configured to be small, the strain distribution of flange portion 11 pressed by end portion 3a of coil spring 3 is represented by the coil spring. 3 can be uniform. Therefore, the whole flange part 11 can be deformed.

  As a result, even when the wall surface 16b of the bolt head recess 16 and the end surface 3b of the coil spring 3 are aligned or close to each other, the escape area of the portion pressed against the end surface 3b of the coil spring 3 can be secured to receive pressure. Concentration of stress can be suppressed. As a result, the occurrence of cracks in the flange portion 11 can be prevented and the breakage can be suppressed.

  7A, when the spring seat rubber 1 is deformed by being pressed by the coil spring 3, the portion between the coil spring 3 and the flange portion 21b is deformed. Accordingly, the bolt head recess 16 is also deformed and crushed toward the flange portion 21b.

  Here, the upper surface of the bolt head 25a (the upper surface in FIG. 7A) is configured as a flat surface, and the upper surface is connected to the outer peripheral surface of the mounting bolt 25a by a curved surface. In addition, as shown in FIG. 7B, in a state where the spring seat rubber 1 is not deformed, the spring seat rubber 1 is in contact with the bottom surface 16a configured as a flat surface without a gap.

  Therefore, when the spring seat rubber 1 is pressed and deformed by the coil spring 3, the bolt head recess 16a of the bolt head recess 16 is deformed according to the shape of the mounting bolt 25a. Even in that case, it is possible to prevent a large force from being locally generated in the thin portion 11c, and to improve the durability of the spring seat rubber 1.

  In addition, the curved surface 16d, which is a connecting surface between the bottom surface 16a and the wall surface 16b, and the curved surface 16e, which is a connecting surface between the bottom surface 16a and the connecting surface 16c, are configured as curved surfaces. Even when the curved surface 16d and the curved surface 16e are in contact with each other, the pressure generated on the curved surface 16d and the curved surface 16e can be prevented from locally increasing, and the durability of the spring seat rubber 1 can be improved. .

  Next, the deformation state of the spring seat rubber 1 will be described with reference to FIG. FIG. 8 is a partial cross-sectional view of the suspension mechanism 100 showing the difference in deformation state of the spring seat rubber 1. FIG. 8A is a partial cross-sectional view showing a deformed state of the spring seat rubber 1 of the suspension mechanism 100 taken along line VIIIa-VIIIa in FIG. FIG. 8B is a partial cross-sectional view of the suspension mechanism 200 showing a deformed state of the spring seat rubber 201 that does not include the inner recess 12 and the overhanging portion 14, and FIG. 8C shows the inner recess. 12 is a partial cross-sectional view of the suspension mechanism 300 showing a deformed state of the spring seat rubber 301 that is not provided with 12. 8B and 8C correspond to the partial cross-sectional view of FIG.

  As shown in FIG. 8B, the spring seat rubber 201 not provided with the inner concave portion 12 and the overhanging portion 14 is sandwiched between the mounting bracket 20 and the coil spring 3, and the coil spring 3 is buried in the spring seat rubber 1. It has been transformed by that.

  Further, since the rubber-like elastic body constituting the spring seat rubber 201 is an incompressible material, a part of the outer shape is deformed by being pushed in by the coil spring 3.

  In the case of the spring seat rubber 201, the fitting cylinder portion 10 is warped outward in the radial direction of the fitting cylinder portion 10 (outside in the left-right direction in FIG. 8) by being pushed in by the coil spring 3. Therefore, a large force is locally generated at a portion of the fitting cylinder portion 10 and between the inner peripheral surface of the ring 13 and the outer peripheral surface of the inner fitting portion 21a.

  Further, as shown in FIG. 8 (b), the flange portion 11 protrudes to the lower side in the radial direction of the fitting tube portion 10 (the lower side in the left and right direction in FIG. 8). A large force is locally generated at the portion of the flange portion 11 on the outer side in the left-right direction.

  Further, the end 3a of the coil spring 3 is close to the distance T5 in the direction along the axis O (vertical direction in FIG. 8) from the metal fitting contact surface 11b. The distance T5 is smaller than the distance T6 and the distance T7 described later, and indicates that the spring seat rubber 1 between the flange portion 21b and the coil spring 3 is thinner than the spring seat rubber 201 and the spring seat rubber 301. ing. Therefore, the rate of reduction of vibration transmitted from the vehicle body side via the coil spring 3 is reduced.

  As shown in FIG. 8C, the spring seat rubber 301 without the inner recess 12 is sandwiched between the mounting bracket 20 and the coil spring 3 in the same manner as the spring seat rubber 201, and the end 3 a of the coil spring 3 is held. Is deformed by being buried in the spring seat rubber 301.

  Similarly to the spring seat rubber 201, since the rubber-like elastic body constituting the spring seat rubber 301 is an incompressible material, a part of the outer shape protrudes by being pushed in by the end portion 3a of the coil spring 3. The shape is deformed.

  In the case of the spring seat rubber 301 as well, the fitting tube portion 10 is warped outward in the radial direction of the fitting tube portion 10 (outside in the left-right direction in FIG. 8), similarly to the spring seat rubber 201. Then, a large force is locally generated at a portion between the inner peripheral surface of the ring 13 and the outer peripheral surface of the inner fitting portion 21a.

  Further, similarly to the spring seat rubber 201, the flange portion 11 protrudes to the lower side outside the fitting cylinder portion 10 in the radial direction (lower side in the left-right direction in FIG. 8). However, as the overhanging portion 14 is disposed, the cross-sectional area of the portion outside the coil spring 3 (outside in the left-right direction in FIG. 8) of the flange portion 11 is increased compared to the spring seat rubber 201.

  Therefore, the force generated when the spring seat rubber 301 is sandwiched between the mounting bracket 20 and the coil spring 3 is dispersed. As a result, compared with the spring seat rubber 201, the shearing force generated at the end surface 3b is reduced, so that the spring seat rubber 301 can be prevented from being damaged.

  Further, as shown in FIGS. 8B and 8C, the force generated when the spring seat rubber 301 is sandwiched between the mounting bracket 20 and the coil spring 3 (the coil spring 3 presses the spring seat rubber 301). Force) is dispersed, the amount of burying of the end 3a of the coil spring 3 in the spring seat rubber 301 is reduced as compared with the spring seat rubber 201. Therefore, the distance along the axis O (vertical direction in FIG. 8) between the end surface 3b of the coil spring 3 and the metal fitting contact surface 11b is a distance T6 larger than the distance T5 (T6> T5). Accordingly, the rate of reduction of vibration transmitted from the vehicle body side via the coil spring 3 is improved.

  That is, the spring seat rubber 301 has a force generated by being sandwiched between the flange portion 21b and the coil spring 3 as compared with the spring seat rubber 201 (the coil spring 3 is provided with the spring seat rubber 301). Force) is distributed, the distance T6 is greater than the distance T5 (T6> T5), and the spring seat rubber 301 between the flange portion 21b and the coil spring 3 is thicker than the spring seat rubber 201. Therefore, the rate of reduction of vibration transmitted from the vehicle body side via the coil spring 3 is improved.

  Here, in the present embodiment, as shown in FIG. 8A, since the inner concave portion 12 and the overhanging portion 14 are provided, in addition to the effect of the spring seat rubber 301, the diameter of the fitting cylindrical portion 10 is increased. It is possible to prevent warping back outward in the direction (outward in the left-right direction in FIG. 8) and jumping out downward (outward in the left-right direction in FIG. 8) radially outward of the fitting cylinder portion 10 of the flange portion 11.

  That is, since the spring seat rubber 1 has the inner recess 12, the protruding portion of the outer shape generated when the end 3 a of the coil spring 3 is embedded in the spring seat rubber 1 is formed between the inner recess 12 and the base portion 21. It can be accommodated in a space S formed therebetween.

  Therefore, the fitting cylinder portion 10 which is a protruding portion of the outer shape is warped back to the outside in the radial direction (outside in the left-right direction in FIG. 8), and the lower side in the radial direction outside the fitting cylinder portion 10 in the flange portion 11 (outside in the left-right direction in FIG. Can be prevented from jumping out to the lower part), so that it is possible to prevent a large force from being locally generated in the flange portion 11 and the fitting cylinder portion 10 and to improve the durability of the spring seat rubber 1. it can.

  Further, as with the spring seat rubber 301, since the overhanging portion 14 is provided, the cross-sectional area of the portion outside the coil spring 3 of the flange portion 11 (outside in the left-right direction in FIG. 8) is increased compared to the spring seat rubber 201. Yes.

  Therefore, the force (the force with which the coil spring 3 presses the spring seat rubber 301) generated when the spring seat rubber 1 is sandwiched between the mounting bracket 20 and the coil spring 3 is dispersed. As a result, compared with the spring seat rubber 301, the shearing force generated at the end surface 3b is reduced, so that the spring seat rubber 1 can be prevented from being damaged.

  Further, as shown in FIGS. 8A and 8B, the force generated when the spring seat rubber 1 is sandwiched between the mounting bracket 20 and the coil spring 3 (the coil spring 3 presses the spring seat rubber 301). ), The amount of the coil spring 3 embedded in the spring seat rubber 1 is reduced as compared with the spring seat rubber 201. Therefore, the distance along the axis O (the vertical direction in FIG. 8) between the end surface 3b of the coil spring 3 and the metal fitting contact surface 11b is a distance T7 larger than the distance T6 (T7> T5). Accordingly, the rate of reduction of vibration transmitted from the vehicle body side via the coil spring 3 is improved.

  In other words, the spring seat rubber 1 has a force generated by being sandwiched between the flange portion 21b and the coil spring 3 as compared with the spring seat rubber 201 (the coil spring 3 is spring seat rubber 301). Is distributed, the distance T7 is greater than the distance T5 (T7> T5), and the spring seat rubber 1 between the flange portion 21b and the coil spring 3 is thicker than the spring seat rubber 201. Therefore, the rate of reduction of vibration transmitted from the vehicle body side via the coil spring 3 is improved.

  In addition, since the inner fitting portion 21 a of the strut mount 2 is fitted to the inner peripheral surface 11 d of the flange portion 11, the flange portion is formed between the flange portion 11 of the strut mount 2 and the end portion 3 a of the coil spring 3. 11 is clamped by the frictional force between the inner peripheral surface 11d of the flange part 11 and the inner fitting part 21a of the strut mount 2, the excessive deformation (distortion of the flange part 11). Generation) can be suppressed, and the durability of the flange portion 11 can be improved.

  In this case, according to the present embodiment, the inner concave portion 12 is formed in the inner peripheral surface 11d of the flange portion 11, and the arrangement angle of the inner concave portion 12 matches the arrangement angle of the projecting portion 14. As described above, even when the inner peripheral surface 11d of the flange portion 11 is locked to the inner fitting portion 21a of the strut mount 2, the arrangement angle of the wall surface 16b of the bolt head recess 16 and the coil spring 3 When the arrangement angle of the end portion 3a of the coil spring 3 matches, the escape area of the portion pressed by the end portion 3a of the coil spring 3 is secured by the inner concave portion 12, and a large force is locally applied to the flange portion 11. It can be prevented from occurring. As a result, the occurrence of cracks in the flange portion 11 can be prevented and the breakage can be suppressed.

  Here, according to the present embodiment, the width dimension W2 of the inner recess 12 is configured to be larger than the width dimension W1 of the bolt head recess 16, so that the arrangement angle of the wall surface 16b of the bolt head recess 16 is When the arrangement angle of the end portion 3a of the coil spring 3 matches, the portion pressed by the end portion 3a of the coil spring 3 can be easily released to the inner concave portion 12, and a large force is locally applied to the flange portion 11. Can be prevented. As a result, the occurrence of cracks in the flange portion 11 can be prevented and the breakage can be suppressed.

  On the other hand, according to the present embodiment, since the width dimension W2 of the inner recess 12 is made smaller than the width dimension W3 of the overhanging portion 14, the arrangement angle of the wall surface 16b of the bolt head recess 16 and the coil spring 3 are set. Even when the arrangement angle of the end portion 3 a coincides with each other, the strain distribution of the flange portion 11 pressed by the end portion 3 a of the coil spring 3 can be made uniform along the coil spring 3. As a result, the occurrence of cracks in the flange portion 11 can be prevented and the breakage can be suppressed.

  That is, when the width dimension W2 of the inner concave portion 12 is larger than the width dimension W3 of the overhanging portion 14, not only the portion pressed by the end 3a of the coil spring 3 but the entire portion near the inner concave portion 12 side Therefore, even if the amount of protrusion of the protruding portion 14 is changed as described above, the strain distribution cannot be made uniform.

  On the other hand, by making the width dimension W2 of the inner concave portion 12 smaller than the width dimension W3 of the overhanging portion 14, the portion of the flange portion 11 pressed by the end portion 3a of the coil spring 3 is released to the inner concave portion 12, The portion in the vicinity thereof is locked by the internal fitting portion 21 a of the strut mount 2, and the strain distribution generated in the flange portion 11 can be made uniform.

  That is, it is possible to suppress the concentration of pressure receiving stress. As a result, the occurrence of cracks in the flange portion 11 can be prevented and the breakage can be suppressed.

  Moreover, in this Embodiment, the fitting cylinder part 10 in which the inner fitting part 21a of the strut mount 2 is fitted is provided, and the fitting cylinder part 10 is provided in a row by the coil contact surface 11a side of the flange part 11. FIG. Thus, since the opening of the inner concave portion 12 on the coil contact surface 11a side of the flange portion 11 is closed, the flange portion 11 is interposed between the flange portion 11 of the strut mount 2 and the end portion 3a of the coil spring 3. Can be prevented from being deformed in a tilted state, and the flange portion 11 can be easily deformed uniformly in the thickness direction (vertical direction in FIG. 1).

  As a result, the distribution of strain generated in the flange portion 11 can be made uniform, and concentration of pressure receiving stress can be suppressed. As a result, the occurrence of cracks in the flange portion 11 can be prevented and the breakage can be suppressed.

  That is, the flange portion 11 of the strut mount 2 and the end portions of the coil spring 3 are not provided with the fitting tube portion 10 and the inner recess 12 is opened on both sides of the metal fitting contact surface 11b and the coil contact surface 11a. When the flange portion 11 is clamped with the flange portion 11, the coil contact surface 11 a side in the vicinity of the inner concave portion 12 of the flange portion 11 is easily displaced toward the inner fitting portion 21 a side of the strut mount 2. Is deformed in a tilted state, and pressure-receiving stress concentrates on a part of the flange portion 11, thereby causing breakage of the flange portion 11 due to generation of a crack.

  On the other hand, according to the present embodiment, by opening the inner concave portion 12 on the coil contact surface 11a side of the flange portion 11, the portion pressed by the end surface 3b of the coil spring 3 as described above can be used as the inner concave portion. 12, while the opening of the inner recess 12 is closed by the fitting cylinder 10 on the coil contact surface 11 a side of the flange 11, the flange 21 b of the strut mount 2 and the end of the coil spring 3 are closed. 3a, when the flange portion 11 is clamped, the coil contact surface 11a side in the vicinity of the inner concave portion 12 of the flange portion 11 is displaced toward the inner fitting portion 21a side of the strut mount 2. It can be received and suppressed by the tube portion 10.

  Therefore, the flange portion 11 can be prevented from being deformed in an inclined state, and the flange portion 11 can be easily deformed uniformly in the thickness direction, so that it is possible to suppress the concentration of pressure receiving stress. As a result, the occurrence of cracks in the flange portion 11 can be prevented and the breakage can be suppressed.

  Next, with reference to FIG.9 and FIG.10, the positional relationship of the recessed part 15 for mechanical clinch of the spring seat rubber 1 and the mechanical clinch 26 of the mounting bracket 20 is demonstrated.

  FIG. 9 is a partial bottom view of a portion of the suspension mechanism 100 in which the mechanical clinch recess 15 is disposed as viewed from the coil spring 3 side toward the strut mount 2 side. In FIG. 9, the end 3 a of the coil spring 3 is hatched for easy understanding of the drawing.

  10A is a cross-sectional view of the suspension mechanism 100 taken along line Xa-Xa in FIG. 9, and FIG. 10B is a cross-sectional view of the suspension mechanism 100 taken along line Xb-Xb in FIG.

  As shown in FIG. 9, the spring seat rubber 1 and the strut mount 2 are overlapped with each other so that their axial centers O coincide with each other, and the axial center O2 extends from the axial center S2 of the connecting surface 15c of the concave portion 15 for mechanical clinch. And the radius R4 which is the distance from the axial center S4 of the mechanical clinch 26 to the axial center O is the same distance (R2 = R4).

  Therefore, if the arrangement angle of the spring seat rubber 1 and the strut mount 2 is matched, the mechanical clinch 26 of the strut mount 2 is accommodated in the mechanical clinch recess 15 of the spring seat rubber 1.

  In addition, a plurality (three in the present embodiment) of the mechanical clinch recesses 15 and a plurality (three in the present embodiment) of mechanical clinch 26 are provided in the circumferential direction of the mounting bracket 20 around the axis O. Are arranged at intervals of a predetermined angle (a central angle of 120 degrees).

  That is, when the spring seat rubber 1 and the strut mount 2 are overlapped, the circumferential mounting angle around the axis O is adjusted so that one mechanical clinch recess 15 and one mechanical clinch 26 overlap. Thus, a plurality (three in the present embodiment) of the mechanical clinch recesses 15 and a plurality (three in the present embodiment) of the mechanical clinch 26 can be overlapped with each other.

  As shown in FIG. 10 (a), the coil spring 3 is disposed above the mechanical clinch projection 26a (above FIG. 10 (a)), and the end 3a of the coil spring 3 and the flange of the strut mount 2 are arranged. The spring seat rubber 1 is compressed with the portion 21b. Therefore, the mechanical clinch recess 15 is deformed, and the height dimension H3 (see FIG. 3) of the mechanical clinch recess 15 is set to a height dimension H31 (H3> H31).

  Further, the height of the concave portion 15 for mechanical clinch 15 (FIG. 10B, vertical dimension) is set to a height dimension H31, and the height of the mechanical clinch protrusion 26a (FIG. 10B, downward dimension) is the height. The dimension is set to H4. The height dimension H3, which is the height dimension before the deformation of the mechanical clinch recess 15, is set to four times the height dimension H4 (H3 = 4 × H4).

  Therefore, the height dimension H31 of the deformed recess 15 for mechanical clinch is maintained at a dimension value (the vertical dimension in FIG. 10B) that is higher than the height dimension H4 of the mechanical clinch protrusion 26a (H31> H4). .

  Therefore, it is possible to prevent the mechanical clinch protrusion 26a from abutting against the bottom surface 15a of the mechanical clinch recess 15 and to prevent a large force from being locally generated in the flange portion 11. As a result, the durability of the spring seat rubber 1 can be improved.

  Further, as shown in FIG. 10B, the curved surface 15d, which is a connecting surface between the bottom surface 15a and the wall surface 15b, is configured as a curved surface, so that even when the mechanical clinch recess 15 is deformed, the curved surface is formed. It is possible to prevent a large force from being locally generated on 15d. As a result, the durability of the curved surface 15d can be improved, and the durability of the spring seat rubber 1 can be improved.

  The present invention has been described above based on the embodiments. However, the present invention is not limited to the above embodiments, and various improvements and modifications can be made without departing from the spirit of the present invention. It can be easily guessed.

  For example, the numerical values (for example, the number, size, angle, etc. of each component) given in the above embodiments are merely examples, and other numerical values can naturally be adopted.

  In the present embodiment, the case in which the shapes of the bolt head recess 16 and the mechanical clinch recess 15 are configured to be open in one direction has been described. However, the present invention is not limited to this, and the bolt head 25a is not necessarily limited thereto. And you may comprise in the circular shape of the magnitude | size corresponding to the mechanical clinch protrusion part 26a.

  In this case, since the number of portions that are built up around the bolt head recess 16 and the mechanical clinch recess 15 increases, the force acting on the bolt head recess 16 and the mechanical clinch recess 15 is dispersed.

  Therefore, the maximum value of the shearing force generated in the bolt head recess 16 and the mechanical clinch recess 15 can be reduced. As a result, the bolt head recess 16 and the mechanical clinch recess 15 are prevented from cracking and breaking, and the durability of the spring seat rubber 1 can be improved.

  Further, in the present embodiment, the case where the bolt head concave portion 16 and the mechanical clinch concave portion 15 are configured to have an opening shape that is open in one direction has been described. However, the present invention is not limited to this. You may comprise in the triangle shape of the magnitude | size corresponding to the head 25a and the mechanical clinch protrusion part 26a, square shape, and a pentagon shape.

  In other words, the bolt head 25 a and the mechanical clinch protrusion 26 a may be accommodated in the bolt head recess 16 and the mechanical clinch recess 15.

It is a fragmentary sectional view of the suspension mechanism in which the spring seat rubber in an embodiment of the invention was assembled. It is a top view of a spring seat rubber. It is sectional drawing of the spring seat rubber in the III-III line of FIG. It is a top view of a strut mount. It is sectional drawing of the strut mount in the VV line | wire of FIG. It is the partial bottom view which looked at the site | part of the suspension mechanism in which the recessed part for volt | bolt heads is arrange | positioned toward the strut mount side from the coil spring side. 7A is a partial cross-sectional view of the suspension mechanism taken along line VIIa-VIIa in FIG. 6, and FIG. 7B is a suspension mechanism showing a state before the coil spring in FIG. 7A is pressed against the strut mount. FIG. 7C is a partial cross-sectional view of the suspension mechanism taken along line VIIc-VIIc in FIG. 6. It is a fragmentary sectional view of a suspension mechanism which shows the difference in the deformation state of a spring seat rubber. (A) is the fragmentary sectional view which showed the deformation | transformation state of the spring seat rubber 1 of the suspension mechanism in the VIIIa-VIIIa line | wire of FIG. (B) is the fragmentary sectional view of the suspension mechanism which showed the deformation | transformation state of the spring seat rubber which is not provided with the inner side recessed part and the overhang | projection part, (c) is the deformation | transformation state of the spring seat rubber which is not provided with the inner side recessed part. It is a fragmentary sectional view of the suspension mechanism which showed. It is the partial bottom view which looked at the site | part of the suspension mechanism in which the recessed part for mechanical clinch is arrange | positioned toward the strut mount side from the coil spring side. (A) is sectional drawing of the suspension mechanism in the Xa-Xa line of FIG. 9, (b) is sectional drawing of the suspension mechanism in the Xb-Xb line of FIG.

Explanation of symbols

100 Suspension mechanism 1 Spring seat rubber 2 Strut mount (mounting device)
3 Coil Spring 3a End 3b End Surface 10 Fitting Tube 11 Flange (Main Body)
11a Coil contact surface (pressure receiving surface)
11b Bracket contact surface (contact surface)
12 Inner recess 14 Overhang (overhang)
15 Mechanical clinch recess 16 Bolt head recess (receiving recess)
20 Mounting bracket 21 Base portion 21a Internal fitting portion 21b Flange portion 21c Partition portion 22 Upper plate 25 Mounting bolt 25a Bolt head (head of fastening bolt)
26 Mechanical clinch R Virtual circle R1, R2, R3, R4 Radius W1 Width (width of receiving recess)
W2 width dimension (width dimension of inner recess)
W3 width dimension (width dimension of overhang)

Claims (3)

In the spring seat rubber, which is composed of a rubber elastic body and is interposed between the flange portion of the mount device and the end portion of the coil spring,
An axially-viewed annular main body part, and a projecting part formed by projecting radially outward from the outer peripheral side of the main body part,
The mounting device includes a fastening bolt fastened to the vehicle body frame side, and a head portion of the fastening bolt protrudes from the flange portion.
The main body portion and the overhanging portion are located on one end side in the axial direction and are in contact with the flange portion of the mount device, and are located on the other end side in the axial direction and face the contact surface. And a pressure receiving surface that receives the end of the coil spring, and a receiving recess that is recessed in the contact surface and receives the head of the fastening bolt,
The phase of the receiving recess is matched with the phase of the overhanging portion, and the overhanging amount of the overhanging portion from the main body is reduced as the distance from the receiving recess is increased. Spring seat rubber. The mount device is provided with a cylindrical inner fitting portion provided continuously to the flange portion, and the inner fitting portion is fitted on the inner peripheral side of the main body portion,
The main body includes an inner recess that is recessed on the inner periphery.
The phase of the inner recess is matched with the phase of the overhang, and the width of the inner recess is larger than the width of the receiving recess and smaller than the width of the overhang. The spring seat rubber according to claim 1. It has an annular shape when viewed from the axial direction, has an outer diameter smaller than that of the main body, and includes a fitting cylinder that is connected to the pressure-receiving surface of the main body. The inner fitting portion of the mounting device is fitted,
3. The spring seat rubber according to claim 2, wherein the inner concave portion is opened on a contact surface side of the main body portion, and a pressure receiving surface side of the main body portion is closed by the fitting tube portion. .

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