This application claims priority under 35 USC 119 to Japanese Patent Application No. 2004-139440, filed on May 10, 2004, the entire contents of which are incorporated herein by reference.
(a) Field of the Invention
This invention relates to a joint structure between members for joining two members together.
(b) Description of the Related Art
As an example of known joint structures for joining two members together, U.S. Pat. No. 6,206,604 (hereinafter, referred to as Patent Document 1) discloses a joint structure between members in which a first member formed to cover a vehicle engine from above is joined to the engine. In the disclosed joint structure, the first member is releasably joined to a second member fixed to the top of the engine and formed in an upwardly extending column. A rubber elastic member is interposed between the first and second members. The elastic member reduces engine vibrations transmitted to the first member.
The elastic member has a cylindrical shape the central axis of which runs vertically, and is accommodated and held in an annular frame formed on the bottom surface of the first member. A tapered hole is formed in the bottom surface of the elastic member to receive a spherical part formed at the top end of the second member. The elastic member has a holding part formed just above the tapered hole. The holding part fits on and holds the spherical part of the second member inserted therein through the tapered hole. The holding part is contiguous with the tapered hole.
The holding part of the elastic member in Patent Document 1 is formed in a substantially spherical shape to cover the spherical part of the second member from its top end to the vicinity of its bottom end. The holding part formed in a substantially spherical shape provides the following effects. First, even if a force is applied which tends to further move the second member relative to the first member in the direction of insertion of the second member with the spherical part of the second member held in the holding part, the top end of the second member is lodged on the top end portion of the holding part to restrain further movement of the second member in the direction of insertion. Second, even if a force is applied which tends to move the second member in the direction of extraction from the elastic member, the lower portion of the spherical part of the second member is lodged in the lower portion of the holding part to prevent easy extraction of the second member. In this manner, the first member can be held in a fixed position.
In molding an elastic member of cylindrical shape having a hole open at its end surface as in Patent Document 1, use is generally made of a mold that is joined and separated in the direction of a central axis of the elastic member.
Particularly when the holding part of the elastic member has a spherical shape as in Patent Document 1, the inside diameter of the holding part gradually decreases from the vertical middle position thereof toward the hole, i.e., downward. If the elastic member of Patent Document 1 is molded using a mold that is vertically joined and separated, an undercut will be formed inside of the holding part. Therefore, in order to allow the removal of the molded elastic member from the mold, a slide core must be employed as part of the mold corresponding to the holding part. This increases the mold cost and makes it difficult to reduce the production cost of the elastic member.
The present invention has been made in view of the foregoing point and therefore its object is to allow the elastic member for joining the first and second members therethrough to be easily molded without any undercut being formed, thereby reducing the production cost of the elastic member.
To attain the above object, an embodiment of a first aspect of the invention is directed to a joint structure between members in which an elastic member is inserted and held in an annular frame provided on a first member and the first member is joined to a second member of columnar shape through the elastic member by inserting a distal end part of the second member into the elastic member. Further, the distal end part of the second member has a small-diameter part a predetermined distance away from the distal end toward the root thereof and a flange closer to the root than the small-diameter part and extending radially outward, the elastic member has a through hole extending in the direction of insertion of the second member and an engagement projection projecting from the inner surface of the through hole, and the joint structure is so constructed that the first and second members are joined together by inserting and holding the elastic member in the annular frame and inserting the distal end part of the second member into the through hole of the elastic member to fit the engagement projection into the small-diameter part and bring the flange into abutment on the end surface of the elastic member located toward the root of the second member.
With the above structure, when the second member is inserted into the through hole of the elastic member inserted and held in the annular frame of the first member, the engagement projection on the inner surface of the through hole is fitted into the small-diameter part of the second member to restrain the extraction of the second member and concurrently the flange of the second member abuts on the end surface of the elastic member located toward the root of the second member to block further movement of the second member in the direction of insertion. In this manner, the first and second members are joined together. Further, when the first member holding the elastic member is relatively pulled with a force exceeding a certain limit in the direction of its withdrawal from the second member, the elastic member is deformed so that the engagement projection is disengaged from the small-diameter part. Thus, the first and second members are separated from each other.
Therefore, the first and second members can be detachably joined, not in a way that the elastic member has a shape with an undercut that would be formed where holding the distal end part of the second member to wrap it spherically like in the related art but in a way that it has a through hole. As a result, the production cost of the elastic member can be reduced.
In an embodiment of a second aspect of the invention, the distal end part of the second member has a small-diameter part a predetermined distance away from the distal end toward the root thereof, the elastic member has a through hole extending in the direction of insertion of the second member, an engagement projection projecting from the inner surface of the through hole, and an engagement projection displacing part that, in inserting the engagement projection into the small-diameter part of the second member, displaces the top end of the engagement projection radially outward to reduce the force of insertion of the engagement projection, and the joint structure is so constructed that the first and second members are joined together by inserting and holding the elastic member in the annular frame and inserting the distal end part of the second member into the through hole of the elastic member to fit the engagement projection into the small-diameter part.
With the above structure, when the second member is inserted into the through hole of the elastic member inserted and held in the annular frame of the first member like the above embodiment of the first aspect of the invention, the engagement projection on the inner surface of the through hole is fitted into the small-diameter part of the second member. Further, when the first member holding the elastic member is relatively pulled with a force exceeding a certain limit in the direction of its withdrawal from the second member, the engagement projection is disengaged from the small-diameter part.
Therefore, the first and second members can be detachably joined, not in a way that the elastic member has a shape with an undercut that would be formed where holding the distal end part of the second member to wrap it spherically like in the related art but in a way that it has a through hole. As a result, the production cost of the elastic member can be reduced.
Further, if the engagement projection obtains a large force holding the second member by enhancing the hardness of the elastic member in order to firmly hold the first member in position, the engagement projection displacing part can displace the top end of the engagement projection radially outward in the course of fitting of the engagement projection into the small-diameter part. Thus, the force of insertion of the second member into the through hole can be reduced.
In another embodiment of the first aspect of the invention, the elastic member has an engagement projection displacing part that, in inserting the engagement projection into the small-diameter part of the second member, displaces the top end of the engagement projection radially outward to reduce the force of insertion of the engagement projection.
With this structure, if, like the above embodiment of the second aspect, the hardness of the elastic member is enhanced in order that the elastic member obtains a large force holding the second member, the force of insertion of the second member into the through hole can be reduced.
In a preferred embodiment, the engagement projection displacing part comprises a mass-reduced part formed to displace the top end of the engagement projection of the elastic member radially outward in inserting the engagement projection into the small-diameter part of the second member.
According to this embodiment, when the engagement projection is fitted into the small-diameter part, it can be displaced radially outward without the complication of the structure of the elastic member.
In the preceding embodiments, the end surface of the elastic member toward the root of the second member is preferably formed with a tool engagement part that engages with a tool for holding the elastic member in inserting the elastic member into the annular frame.
According to this embodiment, when the tool is engaged with the tool engagement part and is then used to insert the elastic member into the annular frame of the first member, the elastic member can be easily aligned with the annular frame. This facilitates the insertion of the elastic member into an adequate position of the annular frame.
Preferably, in the preceding embodiments, the annular frame has a hole that is open at the inner surface thereof, the elastic member has a projection that engages with the hole, and the elastic member is held in the annular frame by inserting the elastic member into the annular frame to fit the projection into the hole.
According to this embodiment, the projection of the elastic member engages with the hole of the annular frame. This prevents the circumferential movement of the elastic member and the movement thereof in the direction of extraction (opposite to the direction of insertion). Therefore, the elastic member can be held in the annular frame with stability and reliability.
In the above embodiment, the elastic member preferably has a recess formed in a portion of the outer surface thereof closer to the root of the second member than the projection to displace the top end of the projection radially inward in fitting the projection into the hole.
With this structure, if the hardness of the elastic member is enhanced to increase the force of engagement between the elastic member and the annular frame, it can be avoided that in the course of insertion of the elastic member into the annular frame, the top end of the projection is displaced backward in the direction of insertion of the elastic member to forcefully slide on the inner surface of the annular frame. Thus, the force of insertion of the elastic member into the annular frame can be reduced.
A preferred embodiment of the present invention will be described below with reference to the drawings. The following description of the preferred embodiment is illustrative only and is not intended to limit the scope, applications and use of the invention.
The engine cover 10 is integrally molded from a resin material. As shown in
A first annular frame 14 extending downward is formed at the joint position located in the vicinity of the middle of said other long edge of the flat plate 11. A mount rubber 30 is inserted into the first annular frame 14. The first annular frame 14 has a circular cross section. As shown in
Furthermore, second annular frames 15 and 15 similar to the first annular frame 14 are formed at the joint positions where the extensions 13 and 13 are joined to the adapters 20 and 20, respectively. As shown in
As shown in
The top end of the adapter 20 is formed, as shown in
The adapter 20 also has a circular flange 27 formed under the hexagonal part 26 to extend radially outward. The bottom surface of the flange 27 is a flat surface substantially orthogonal to the central axis of the adapter 20. The top surface of the flange 27 is an inclined surface that goes down radially toward the outside of the flange 27.
The mount rubber 30 is integrally molded from rubber. The mount rubber 30 to be inserted into the first annular frame 14 has the same shape as the mount rubber 30 to be inserted into the second annular frame 15. As shown in
As shown in
As shown in
The vertical middle of the inner surface of the through hole 31 is formed with an engagement projection 33 that protrudes radially inward. The engagement projection 33 is circumferentially continuous. As shown in
As shown in
As shown in
As also shown in
Next, the manner of joining of the engine cover 10 to each adapter 20 will be described. First, one mount rubber 30 is accommodated into the first annular frame 14 of the engine cover 10. In this case, the mount rubber 30 is held by a tool by fitting the tool into the tool engagement parts 36, and the tool is used to gradually insert the mount rubber 30 into the first annular frame 14 through its opening 14b with the projections 30b of the mount rubber 30 aligned with the holes 14a of the first annular frame 14. In the course of insertion of the mount rubber 30 into the first annular frame 14, the projections 30b of the mount rubber 30 are easily displaced toward the recesses 37. Then, as shown in
Thereafter, the engine cover 10 is moved so that the top ends of the adapters 20 are located below the through holes 31 of the associated mount rubbers 30. Next, when the engine cover 10 is pushed down as shown in the arrow X in
On the other hand, in separating the engine cover 10 from the adapter 20, the engine cover 10 is lifted up to extract the adapter 20 from the through hole 31 of the mount rubber 30. In this case, as the engagement projection 33 of the mount rubber 30 rides on the large-diameter part 24, it elastically deforms to fully disengage from the small-diameter part 25. In this manner, the engine cover 10 is separated from the adapter 20.
In this case, since each of the mount rubbers 30 is engaged with the first or second annular frames 14 or 15, each at two positions, i.e., the projections 30b and the rib 32, the mount rubbers 30 can be prevented from being extracted from the first and second annular frames 14 and 15 prior to the disengagement from the adapters 20.
As described above, in the present embodiment, each mount rubber 30 with a through hole 31 is inserted and held in an associated one of the first and second annular frames 14 and 15 of the engine cover 10 and the associated adapter 20 is inserted into the through hole 31 of the mount rubber 30 to fit the engagement projection 33 into the small-diameter part 25. Since, thus, the through hole 31 is formed in the mount rubber 30 unlike the related art in which the mount rubber has a shape with an undercut that would be formed where holding the top end of the adapter 20 to wrap it spherically, the engine cover 10 can be joined detachably to the adapter 20 and can be held in position. Therefore, the need for employing a slide core as part of a mold for the mount rubber 30 is eliminated, resulting in reduced cost of the mount rubber 30.
Further, the mount rubber 30 is formed with an engagement projection displacing part for reducing the force of insertion of the adapter 20 into the rubber mount 30. Therefore, if the hardness of the mount rubber 30 is enhanced in order to securely hold the engine cover 10 on the adapter 20, the force of insertion of the adapter 20 into the through hole 31 can be reduced. This facilitates the assembly work of the engine cover 10.
Furthermore, since the engagement projection displacing part is formed of mass-reduced parts 38, this prevents the structure of the mount rubber 30 from being complicated, resulting in reduced cost of the mount rubber 30 and facilitated assembly work of the engine cover 10.
Furthermore, tool engagement parts 36 are formed in the end surface of each mount rubber 30 located backward in the direction of insertion, so that the mount rubber 30 can inserted into the first or second annular frame 14 or 15 after it is held at its tool engagement parts 36 by a tool. This eliminates the need for checking the positions of the projections 30b in inserting the mount rubber 30 in the annular frame 14 or 15. Therefore, the workability of assembly of the mount rubber 30 with the engine cover 10 can be improved.
Furthermore, the mount rubber 30 is formed with recesses 37 so that the top ends of the projections 30b can be displaced radially inward and toward the recesses 37 in inserting the mount rubber 30 into the annular frame 14 or 15. Therefore, it can be avoided that the projections 30b forcefully slide on the inner surface of the annular frame 14 or 15. Further, the increase in the insertion force can be thereby suppressed, which facilitates the insertion of the mount rubber 30 into the annular frame 14 or 15. As a result, the workability of assembly of the mount rubber 30 with the annular frame 14 or 15 can be improved.
In the above embodiment, the mass-reduced parts 38 for reducing the insertion force are formed in the outer surface of the mount rubber 30. For example, as in a first modification of the above embodiment shown in
Alternatively, as in a second modification of the above embodiment shown in
In the first and second modifications, even if the center of the through hole 31 of the mount rubber 30 inserted in the annular frame 14 or 15 is misaligned with the center of the adapter 20 mounted on the engine, the engagement projection 33 is displaced so that the adapter 20 can be inserted into the mount rubber 30 with ease.
In the first and second modifications, the mass-reduced parts 38 in the outer periphery of the mount rubber 30 may be dispensed with.
The shape of each mass-reduced part is not limited to that in the above embodiment and modifications.
Further, the present invention is applicable to other cases than where the engine cover 10 is joined to the adapter 20.
As can be seen from the above, the joint structure between members according to the present invention can be used such as where an engine cover is mounted on an engine.
Number | Date | Country | Kind |
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2004-139440 | May 2004 | JP | national |