The disclosure of Japanese Patent Application No. 2017-051810 filed on Mar. 16, 2017 including the specification, drawings and abstract, is incorporated herein by reference in its entirety.
The present invention relates to a method for manufacturing a worm reducer, a worm reducer manufactured by the manufacturing method, and an electric power steering system including the worm reducer.
Japanese Patent Application Publication No. 2015-187461 (JP 2015-187461 A) and Japanese Patent Application Publication No. 2012-91653 (JP 2012-91653 A) disclose a worm reducer including a worm wheel, a worm shaft that meshes with the worm wheel, and a housing that houses the worm wheel and the worm shaft. The worm reducer has a structure in which a coil spring urges the worm shaft toward the worm wheel in order to reduce a backlash between the worm shaft and the worm wheel. The housing includes a worm shaft housing portion that houses the worm shaft, and a coil spring housing portion that houses the coil spring.
The coil spring housing portion of the worm reducer of JP 2015-187461 A communicates with the worm shaft housing portion and the outside of the housing. When assembling the worm reducer, the worm shaft is arranged, then the coil spring is arranged from the outside of the housing, and then the opening of the coil spring housing portion is closed by a cap. As a result, the coil spring is elastically deformed by being sandwiched between the cap and the worm shaft, thereby urging the worm shaft toward the worm wheel.
The coil spring housing portion of the worm reducer of JP 2012-91653 A does not communicate with the outside of the housing from the worm shaft housing portion. That is, the coil spring housing portion does not have an opening to the outside of the housing. Therefore, the cap provided in the worm reducer of JP 2015-187461 A is not necessary, whereby the number of components can be reduced. When the worm shaft is arranged in the worm shaft housing portion in the assembling of the worm reducer of JP 2012-91653 A, however, the coil spring cannot be inserted into the coil spring housing portion afterwards. Thus, the worm shaft needs to be inserted into the worm shaft housing portion after the coil spring is arranged in the coil spring housing portion. The coil spring is not compressed before the worm shaft is inserted into the worm shaft housing portion. Therefore, a part of the coil spring is located in the worm shaft housing portion. Thus, the part of the coil spring obstructs the insertion of the worm shaft into the worm shaft housing portion.
It is one object of the present invention to provide a method for manufacturing a worm reducer, a worm reducer, and an electric power steering system, in which assembling workability is improved.
A method for manufacturing a worm reducer according to one aspect of the present invention has the following features in its structure. That is, this method is a method for manufacturing a worm reducer in which an elastic member urges a worm shaft housed in a housing toward a worm wheel. The method includes an elastic member arranging step, a jig inserting step, a worm shaft inserting step, and a jig removing step. The elastic member arranging step is a step of arranging the elastic member in a recess formed on an inner face of the housing. The jig inserting step is a step of inserting a jig into the housing, and compressing the elastic member by the jig. The worm shaft inserting step is a step of inserting the worm shaft into the housing after the jig inserting step. The jig removing step is a step of removing the jig from the housing.
The foregoing and further features and advantages of the invention will become apparent from the following description of example embodiments with reference to the accompanying drawings, wherein like numerals are used to represent like elements and wherein:
An embodiment of the present invention is described below in detail with reference to the accompanying drawings.
The steering mechanism 3 includes a steering shaft 8 configured to rotate in association with rotation of the steering wheel 5. The steering shaft 8 includes a column shaft 9, an intermediate shaft 10, and a pinion shaft 11. The column shaft 9 includes an input shaft 9a, an output shaft 9b, and a torsion bar 9c. The input shaft 9a is coupled to the steering wheel 5. The output shaft 9b is coupled to the intermediate shaft 10. The torsion bar 9c coaxially couples the input shaft 9a and the output shaft 9b to each other.
The output shaft 9b is coupled to the intermediate shaft 10 via a universal joint 12. The intermediate shaft 10 is coupled to the pinion shaft 11 via a universal joint 13. A pinion 11a is formed on the pinion shaft 11.
The steering operation mechanism 4 includes a rack shaft 14 and tie rods 15. A rack 14a is formed on the rack shaft 14. The rack 14a meshes with the pinion 11a. Each tie rod 15 has one end coupled to the rack shaft 14, and the other end coupled to the steered wheel 6.
When the steering wheel 5 is rotated in response to the driver's operation of the steering wheel 5, the pinion shaft 11 is rotated via the column shaft 9 and the intermediate shaft 10. The rotation of the pinion shaft 11 is converted into axial reciprocating motion of the rack shaft 14 by a rack and pinion mechanism. The reciprocating motion of the rack shaft 14 changes the steered angles of the steered wheels 6.
The assist mechanism 7 includes a torque sensor 16, a vehicle speed sensor 17, an electronic control unit (ECU) 18, an electric motor 19, and the worm reducer 1. The torque sensor 16 detects a steering torque T based on a torsion amount between the input shaft 9a and the output shaft 9b. The ECU 18 determines an assist torque based on the steering torque T detected by the torque sensor 16 and a vehicle speed V detected by the vehicle speed sensor 17. Driving of the electric motor 19 is controlled by the ECU 18. A rotational force (power) of the electric motor 19 is transmitted to the output shaft 9b of the column shaft 9 of the steering shaft 8 via the worm reducer 1. As a result, the assist torque is applied to the output shaft 9b, thereby assisting the driver's steering operation.
In this embodiment, a so-called column assist type electric power steering system is described as an example. In the column assist type electric power steering system, the power of the electric motor 19 is applied to the column shaft 9. The present invention is not limited to the column assist type electric power steering system, but is applicable to an electric power steering system including a worm reducer. Next, the structure of the worm reducer 1 is described.
The worm wheel 24 is coupled to the output shaft 9b of the column shaft 9 so as to be rotatable together with the output shaft 9b. The worm wheel 24 includes an annular metal core 24a and a resin member 24b. The metal core 24a is coupled to the output shaft 9b so as to be rotatable together with the output shaft 9b. The resin member 24b is externally fitted to the metal core 24a. A toothing 24c is formed on the resin member 24b. The toothing 24c of the worm wheel 24 meshes with the toothing 21c of the worm shaft 21.
The worm shaft 21 is arranged substantially coaxially with an output shaft 19a of the electric motor 19. The second end 21b of the worm shaft 21 and the end of the output shaft 19a of the electric motor 19 are coupled to each other via a power transmission joint 27 in a torque transmissible and pivotable manner. The power transmission joint 27 includes a first rotation element 27a, a second rotation element 27b, and an intermediate element 27c. The first rotation element 27a is coupled to the second end 21b of the worm shaft 21 so as to be rotatable together with the worm shaft 21. The second rotation element 27b is coupled to the output shaft 19a of the electric motor 19 so as to be rotatable together with the output shaft 19a. The intermediate element 27c is interposed between the first rotation element 27a and the second rotation element 27b, and transmits a torque between the rotation elements 27a and 27b. The intermediate element 27c is formed of an elastic body such as rubber.
A first bearing 22 is attached to the first end 21a of the worm shaft 21. The first end 21a of the worm shaft 21 is rotatably supported on the housing 20 via the first bearing 22. A second bearing 23 is attached to the second end 21b of the worm shaft 21. The second end 21b of the worm shaft 21 is rotatably supported on the housing 20 via the second bearing 23. The intermediate element 27c of the power transmission joint 27 is elastically deformed to allow the worm shaft 21 to pivot about a bearing center of the second bearing 23 relative to the output shaft 19a of the electric motor 19.
For example, the first bearing 22 is a ball bearing. The first bearing 22 includes an inner ring 40, an outer ring 41, and a plurality of rolling elements 42. The inner ring 40 of the first bearing 22 is fitted to a fitting recess 43 provided on the outer periphery of the first end 21a of the worm shaft 21. Therefore, the inner ring 40 is rotatable together with the worm shaft 21. The inner ring 40 abuts against a positioning stepped portion 44 in the axial direction X. The positioning stepped portion 44 is provided on the outer periphery of the first end 21a of the worm shaft 21. Thus, axial movement of the inner ring 40 relative to the worm shaft 21 is restricted.
For example, the second bearing 23 is a ball bearing. The second bearing 23 includes an inner ring 30, an outer ring 31, and a plurality of rolling elements 32. The inner ring 30 of the second bearing 23 is fitted to the second end 21b of the worm shaft 21 by clearance fit so as to be rotatable together with the worm shaft 21. The outer ring 31 is held between a positioning stepped portion 34 and a clamping member 35 in the axial direction X. The positioning stepped portion 34 is provided on the housing 20. The clamping member 35 is threadedly fitted to a thread portion provided on an inner face 20a of the housing 20. Thus, axial movement of the outer ring 31 is restricted.
For example, the elastic member 25 is a compression coil spring. The elastic member 25 urges the worm shaft 21 toward the worm wheel 24. The cushioning member 26 is an elastic body such as rubber. The cushioning member 26 is arranged between the worm shaft 21 and the housing 20. The housing 20 has an internal space 28 that houses the worm shaft 21, the worm wheel 24, the elastic member 25, the cushioning member 26, the lid member 51, and the like. The internal space 28 is defined by the inner face 20a of the housing 20. The internal space 28 includes a worm shaft housing space 100, a worm wheel housing space 110, a recess 120, a first opening 50, and a second opening 55.
The worm shaft housing space 100 houses the worm shaft 21. The worm wheel housing space 110 houses the worm wheel 24. The recess 120 communicates with the worm shaft housing space 100. Each of the openings 50 and 55 allows the worm shaft housing space 100 and the outside of the internal space 28 to communicate with each other. The worm shaft housing space 100 has a substantially cylindrical shape extending in the axial direction X. The worm shaft housing space 100 includes a first end housing portion 101, a second end housing portion 102, and a toothing housing portion 103.
The first end housing portion 101 houses the first end 21a and the first bearing 22 attached to the first end 21a. The first end housing portion 101 is one end of the worm shaft housing space 100 in the axial direction X. The first end housing portion 101 is a movement hole in which the first bearing 22 is retainable so as to be movable in a direction in which a core-to-core distance D1 between the worm shaft 21 and the worm wheel 24 increases or decreases (see
The second end housing portion 102 houses the second end 21b, the second bearing 23 attached to the second end 21b, and the power transmission joint 27 coupled to the second end 21b. The second end housing portion 102 is the other end of the worm shaft housing space 100 in the axial direction X. The second opening 55 is formed at the other end of the housing 20 in the axial direction X. The second end housing portion 102 communicates with the outside of the internal space 28 via the second opening 55.
The toothing housing portion 103 houses the toothing 21c. The toothing housing portion 103 communicates with the worm wheel housing space 110.
Referring to
The recess 120 is formed on the inner face 20a of the housing 20 at the part that defines the first end housing portion 101 (on the inner face 20a at one end of the housing 20). The recess 120 includes an elastic member housing recess 70 (second recess) and a cushioning member engaging recess 80 (first recess). Referring to
Referring to
The facing surface 83 is constituted by a first face 83a, a second face 83b, and an inclined face 83c. The first face 83a, the inclined face 83c, and the second face 83b are arrayed in this order from the first opening 50 side in the axial direction X. The first face 83a extends in the axial direction X. The second face 83b extends in the axial direction X on a radially inner side (worm shaft housing space 100 side) with respect to the first face 83a and on the side opposite to the first opening 50 side across the first face 83a. The second face 83b is coupled to the axial end face 81. The inclined face 83c couples the first face 83a and the second face 83b to each other, and is inclined in the radially inward direction (closer to the worm shaft housing space 100) toward the side opposite to the first opening 50 side. The second face 83b is a flat face orthogonal to the radial direction R of the worm shaft 21.
The elastic member housing recess 70 is formed on the second face 83b of the facing surface 83 of the cushioning member engaging recess 80. The elastic member housing recess 70 is a bottomed cylindrical hole extending in the radial direction R from the second face 83b. The elastic member housing recess 70 communicates with the first end housing portion 101 of the worm shaft housing space 100 via the cushioning member engaging recess 80. The elastic member housing recess 70 houses at least a part of the elastic member 25 (see
As illustrated in
Referring to
Referring to
The elastic member 25 is inserted through the elastic member guiding portion 62. The elastic member guiding portion 62 passes through the engagement portion 61. The end of the elastic member guiding portion 62 opposite to the first opening 50 side in the axial direction X is open to the outside of the engagement portion 61. The engagement portion 61 has a closing face 61a and an opening face 61b that are arranged away from each other in the axial direction X. Referring to
Next, a method for assembling the worm reducer 1 is described with reference to
Next, as illustrated in
The facing surface 83 of the cushioning member engaging recess 80 includes the inclined face 83c, and therefore the jig 95 can smoothly be inserted into the cushioning member engaging recess 80. In order that the jig 95 can smoothly compress the elastic member 25, an inclined face 95a that faces the inclined face 83c may be provided at the distal end of the jig 95. In order that the jig 95 can smoothly compress the elastic member 25, the jig 95 may be inserted into the cushioning member engaging recess 80 by moving the jig 95 to a position where the jig 95 faces the facing surface 83 (moving the jig 95 from a position indicated by a long dashed double-short dashed line to a position indicated by a long dashed short dashed line) and then moving the jig 95 closer to the facing surface 83.
Next, as illustrated in
Next, as illustrated in
Next, as illustrated in
Although illustration is omitted, the clamping member 35 is then threadedly fitted to the thread portion provided on the inner face 20a of the housing 20, and the output shaft 19a of the electric motor 19 is coupled to the second end 21b of the worm shaft 21 via the power transmission joint 27. The worm wheel 24 is inserted into the housing 20, and the toothing 24c of the worm wheel 24 is meshed with the toothing 21c of the worm shaft 21. The assembling (manufacturing) of the worm reducer 1 is completed after other necessary members are attached.
According to this embodiment, the jig inserting step is executed before the worm shaft inserting step. Through the compression of the elastic member 25 by the jig 95, the elastic member 25 can be retreated from the space inside the housing 20 where the worm shaft 21 is inserted (worm shaft housing space 100). Therefore, the worm shaft 21 can smoothly be inserted into the housing 20 without being hindered by the elastic member 25.
The jig removing step is executed after the worm shaft inserting step. Thus, the elastic member 25 released from the compression by the jig 95 abuts against the worm shaft 21, and urges the worm shaft 21 toward the worm wheel 24. By adding the simple steps that are the jig inserting step and the jig removing step in the method for manufacturing the worm reducer 1, in which the worm shaft inserting step is executed after the elastic member arranging step, the worm shaft 21 can easily be arranged at an appropriate position in the housing 20 (in the worm shaft housing space 100) without being obstructed by the elastic member 25. Thus, the assembling workability of the worm reducer 1 can be improved.
According to this embodiment, the recess 120 is formed on the inner face 20a of the housing 20 at the part that defines one end of the worm shaft housing space 100 in the axial direction X (on the inner face 20a at one end of the housing 20). The first opening 50 to be closed by the lid member 51 after the jig removing step communicates with one end of the worm shaft housing space 100 in the axial direction X. That is, the first opening 50 is formed in the vicinity of the recess 120. In the elastic member arranging step, the elastic member 25 is inserted into the recess 120 (specifically, the elastic member housing recess 70) inside the housing 20 via the first opening 50 formed in the vicinity of the elastic member housing recess 70. Therefore, the arrangement of the elastic member 25 in the elastic member housing recess 70 is facilitated as compared to the structure without the first opening 50. In the jig inserting step, the jig 95 is inserted into the housing 20 via the first opening 50 formed in the vicinity of the recess 120. Therefore, the movement distance of the jig 95 inside the housing 20 is shorter than that of the structure without the first opening 50. Thus, the insertion and removal of the jig 95 into and from the housing 20 are facilitated. Accordingly, the assembling workability of the worm reducer 1 can be improved.
The machine tool 90 can be inserted into the housing 20 via the first opening 50. Therefore, the formation of the elastic member housing recess 70 is also facilitated. According to this embodiment, the elastic member housing recess 70 is formed on the bottom face of the cushioning member engaging recess 80 (second face 83b of the facing surface 83) that is formed on the inner face 20a of the housing 20. By inserting the jig 95 into the cushioning member engaging recess 80 in the jig inserting step, the elastic member 25 can be compressed. Therefore, the jig 95 is not an obstacle in the subsequent worm shaft inserting step. The cushioning member engaging recess 80 is open to the first opening 50 side. Therefore, the jig 95 can easily be pulled out from the first opening 50 side in the jig removing step. Thus, the assembling workability of the worm reducer 1 can be improved.
In a structure without the cushioning member 26, the first bearing 22 attached to the worm shaft 21 and the housing 20 strike against each other due to displacement of the first bearing 22. Therefore, striking noise is generated due to the strike between metals. By arranging the cushioning member 26 between the worm shaft 21 and the inner face 20a of the housing 20 in the cushioning member inserting step as in this embodiment, the generation of striking noise can be suppressed. In the cushioning member inserting step, the cushioning member 26 (engagement portion 61 of the cushioning member 26) engages with the cushioning member engaging recess 80 so as not to be rotatable in the circumferential direction C. Therefore, the cushioning member engaging recess 80 where the jig 95 is inserted in the assembling process of the worm reducer 1 can also be used as a locking structure for preventing the rotation of the cushioning member 26 in the circumferential direction C. Thus, there is no need to provide a recess for preventing the rotation of the cushioning member 26 in the housing 20 separately from the elastic member housing recess 70 or the cushioning member engaging recess 80.
The present invention is not limited to the embodiment described above, but various modifications may be made within the scope of claims. For example, the cushioning member engaging recess 80 need not be provided on the inner face 20a of the housing 20. In this case, the elastic member housing recess 70 is formed on the inner face 20a of the housing 20 at an annular surface that defines the first end housing portion 101. Also in this case, as illustrated in
Regarding other features, various modifications may be made to the present invention within the scope of claims.
Number | Date | Country | Kind |
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2017-051810 | Mar 2017 | JP | national |