JP2017125582A - Differential device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a differential device capable of checking the presence/absence of a pin even after assembling, and capable of easily taking out the pin even after disassembling.SOLUTION: A first pin hole 42 storing one end of a holding pin 30 penetrates to the outside of a case, so that the presence/absence of the holding pin 30 can be visually checked even after assembling. When disassembling, the holding pin 30 can be easily taken out by pushing out the holding pin 30 from the penetrating pin hole 42 side. The first pin hole 82 storing one end of the holding pin 30 has a diameter of a small-diameter pin hole 82b communicating with the outside of the case smaller than a diameter of the holding pin 30, so that the holding pin 30 is prevented from slipping off to the outside of the case.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a differential device, and more particularly to the structure of a differential case of a differential device.

  A differential mechanism comprising a pinion shaft, a pinion gear rotatably fitted on the outer periphery of the pinion shaft, a pair of side gears meshing with the pinion gear, and a differential case that houses the differential mechanism The differential apparatus comprised by is well known. In addition, a case in which a differential case is composed of two case members has been proposed. This is the differential device of Patent Document 1. In the differential device of Patent Document 1, a pin for fixing a pinion shaft is inserted into a pin hole in a state where the case member is divided, and the case member is coupled after the insertion. Thus, after the differential device is assembled, the pin is embedded in the pin hole.

JP 2012-92982 A JP 2008-128440 A

  By the way, in the differential apparatus of patent document 1, since the pin hole does not penetrate the case exterior, the pin does not fall out of the pin hole, but the presence or absence of the pin cannot be confirmed from the exterior of the case after assembly. . Also, when disassembling the differential device for inspection or repair, it is possible to take out the pin by dividing the case member, but it is difficult to immediately pull out the pin from the pin hole due to restrictions on design requirements. It was necessary to drag out the pin using a pick or the like.

  The present invention has been made against the background of the above circumstances. The purpose of the present invention is to provide a differential that can confirm the presence or absence of a pin even after assembly and can easily take out the pin even after disassembly. To provide an apparatus.

  The gist of the first invention is that: (a) a differential mechanism comprising a pinion shaft, a pinion gear rotatably fitted on the outer periphery of the pinion shaft, and a pair of side gears meshing with the pinion gear; A differential case configured to include a differential case configured of two case members and accommodating the differential mechanism, (b) a through hole into which the pinion shaft is fitted in one of the case members And pin holes are formed to accommodate both ends of the pins that pass through the pinion shaft in the radial direction, and (c) the pin holes on the side accommodating the one ends of the pins communicate with the outside of the case. And the diameter of the hole communicating with the through hole in the longitudinal direction is larger than the diameter of the pin, while the diameter communicating with the outside of the case in the longitudinal direction. Diameter, characterized in that it is formed smaller than the diameter of the pin.

  According to the differential device of the first invention, the pin hole that accommodates one end of the pin communicates to the outside of the case member, so that the presence or absence of the pin can be visually confirmed even after assembly. Moreover, in the case of decomposition | disassembly, a pin can be easily taken out by pushing out a pin from the pin hole side which penetrated. Further, since the pin hole on the side that accommodates one end of the pin has a smaller diameter on the side communicating with the outside of the case than the diameter of the pin, the pin is also prevented from dropping off to the outside of the case.

It is sectional drawing of the differential apparatus with which this invention was applied suitably. It is the expanded sectional view which expanded the site | part shown with a thick continuous line about the 1st case member and 2nd case member of FIG. It is sectional drawing of the differential apparatus which is another Example of this invention. It is the expanded sectional view which expanded the site | part shown with a thick continuous line about the 1st case member and 2nd case member of FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following embodiments, the drawings are appropriately simplified or modified, and the dimensional ratios, shapes, and the like of the respective parts are not necessarily drawn accurately.

  FIG. 1 is a cross-sectional view of a differential apparatus 10 to which the present invention is preferably applied. The differential device 10 is a so-called Babel gear type differential device using a bevel gear. The differential device 10 is held in a housing 12 that is a non-rotating member so as to be rotatable around an axis C1 via a pair of bearings 11a and 11b. The axis C1 is a rotation axis of a drive shaft (not shown) that is spline fitted to the side gear 20 and the side gear 20 described later.

  The differential device 10 rotates integrally with the differential case 14 around the axis C1 by holding both ends of the differential case 14 around the axis C1 in the housing 12 via a pair of bearings 11a and 11b and the differential case 14 being held at both ends. The pinion shaft 16 that rotates, the pinion gear 18 that is rotatably fitted to the outer periphery of the pinion shaft 16, a pair of side gears 20 that mesh with the pinion shaft 18 and that can rotate about the axis C1, and a differential case by a bolt (not shown) 14 and a ring gear 28 fixed to 14. The pinion shaft 16, the pinion gear 18, and the pair of side gears 20 constitute a differential mechanism 21 of the present invention, and the differential mechanism 21 is accommodated in the differential case 14.

  The differential case 14 includes two case members, a first case member 14a and a second case member 14b, and is coupled to each other by a bolt (not shown). The first case member 14a and the second case member 14b are divided into two on the left and right with the axis C2 of the pinion shaft 16 shown in FIG. 1 as a boundary. That is, the differential case 14 is divided into two parts, that is, a first case member 14a and a second case member 14 that are perpendicular to the axis C1 and overlapped with the axis C2, and are coupled to each other by bolts (not shown). ing. The first case member 14a corresponds to one of the case members of the present invention.

  The first case member 14a is formed in a substantially bowl shape with one opening, and is supported by the bearing 11a so as to be rotatable around the axis C1. A cylindrical portion 22 into which a drive shaft (not shown) is fitted is formed on the side opposite to the opening in the axis C1 direction of the first case member 14a. A bearing 11a is provided on the outer peripheral side of the cylindrical portion 22, and the first case member 14a is rotatably supported around the axis C1 via the bearing 11a.

  Similarly, the second case member 14b is formed in a substantially bowl shape with one opening, and a cylindrical portion 24 into which a drive shaft (not shown) is fitted is formed on the opposite side of the opening in the axis C1 direction of the second case member 14b. Has been. A bearing 11b is provided on the outer peripheral side of the cylindrical portion 24, and the second case member 14b is rotatably supported around the axis C1 via the bearing 11b.

  The mating surface 23 (see FIG. 2) formed on the opening side of the first case member 14a and the mating surface 25 (see FIG. 2) formed on the opening side of the second case member 14b are in contact with each other. The differential case 14 is integrally configured by being fastened by a bolt (not shown).

  The pinion shaft 16 has a cylindrical shape, and both ends thereof are held by the differential case 14. Accordingly, the pinion shaft 16 is rotated around the axis C <b> 1 together with the differential case 14. The differential case 14 is formed with a pair of through holes 26 communicating the inside and the outside, and both ends of the pinion shaft 16 are fitted into the through holes 26. The through hole 26 has a semicircular recess in cross section formed in the mating surface 23 of the first case member 14a, and a semicircular recess in cross section formed in the mating surface 25 of the second case member 14b. Are superimposed on each other. The pinion shaft 16 is fixed so as not to drop off by a holding pin 30 that penetrates the pinion shaft 16 in the radial direction. A mechanism for fixing the pinion shaft 16 by the holding pins 30 will be described later. The holding pin 30 corresponds to the pin of the present invention.

  A pair of pinion gears 18 are fitted on the outer periphery of the pinion shaft 16 so as to be rotatable around the axis C <b> 2 of the pinion shaft 16. The pinion gear 18 is revolved around the axis C1 when the pinion shaft 16 rotates.

  The pair of side gears 20 are arranged so as to face each other across the pinion shaft 16 around the axis C1. The pair of side gears 20 are meshed with the pinion gear 18, respectively.

  In the differential device 10, when power is transmitted to the ring gear 28, the power is transmitted to a drive shaft (not shown) via the differential case 14, the pinion shaft 16, the pinion gear 18, and the side gear 20. Here, the pinion gear 18 does not rotate during straight traveling, but the rotation of the pinion gear 18 according to the steering angle gives a difference in rotational speed between the left and right side gears 20 during cornering. .

  FIG. 2 is an enlarged cross-sectional view of the first case member 14a and the second case member 14b of FIG. In FIG. 2, the alternate long and short dash line indicates a pinion shaft 16 fixed to the differential case 14, and the alternate long and two short dashes line indicates a holding pin 30 for fixing the pinion shaft 16.

  The first case member 14a and the second case member 14b are fastened by bolts (not shown) in a state where the mating surfaces 23 and 25 are overlapped with each other. In addition, the fastening part of the said bolt is formed in the site | part in which the through-hole 26 is not formed in the circumferential direction in the opening side of the 1st case member 14a and the 2nd case member 14b.

  A through hole 26 is formed in the differential case 14, and one end in the longitudinal direction of the pinion shaft 16 indicated by a one-dot chain line is fitted into the through hole 26. A through hole 38 that penetrates the pinion shaft 16 in the radial direction is formed in the pinion shaft 16, and a holding pin 30 indicated by a two-dot chain line is inserted through the through hole 38.

  The differential case 14 is formed with pin holes 40 that accommodate both ends of the holding pin 30 that penetrates the pinion shaft 16 in the radial direction. The pin hole 40 is formed in a longitudinal shape with a circular cross section. The pin hole 40 is formed by a first pin hole 42 that accommodates one end of the holding pin 30 and a second pin hole 44 that accommodates the other end of the holding pin 30. In addition, the 1st pin hole 42 respond | corresponds to the pin hole of the side which accommodates the end of the pin of this invention.

  The first pin hole 42 has one end in the longitudinal direction communicating with the through hole 26 and the other end communicating with the outside of the case. That is, the first pin hole 42 penetrates to the outside of the case. The first pin hole 42 communicates with the through hole 26 and communicates with the outside of the case with a large-diameter pin hole 42a having a hole diameter larger than the diameter of the holding pin 30, and the hole diameter is the diameter of the holding pin 30. Smaller diameter pin hole 42b. A stepped portion 46 is formed between the large diameter pin hole 42a and the small diameter pin hole 42b. Thus, the first pin hole 42 is a stepped through hole having a stepped portion 46 between the large diameter pin hole 42a and the small diameter pin hole 42b.

  The holding pin 30 accommodated on the first pin hole 42 side is substantially accommodated in a large-diameter pin hole 42a set to a diameter of a hole capable of accommodating the holding pin 30. Here, when the holding pin 30 moves in the large-diameter pin hole 42a in the longitudinal direction toward the small-diameter pin hole 42b, the end in the longitudinal direction of the holding pin 30 is aligned with the axis C1 formed in the stepped portion 46. Since it contacts the vertical surface, the stepped portion 46 functions as a retaining pin 30 and prevents the holding pin 30 from moving toward the small diameter pin hole 42b. Accordingly, the holding pin 30 is prevented from dropping out of the case from the first pin hole 42.

  The second pin hole 44 has a diameter larger than the diameter of the holding pin 30 so that one end communicates with the through hole 26 and the holding pin 30 can be accommodated. Further, the second pin hole 44 does not penetrate to the outside of the case and is closed by the second case member 14b. Therefore, after the assembly, since it is accommodated in the second case member 14b, the holding pin 30 accommodated in the second pin hole 44 is prevented from dropping out of the case.

  In the differential device 10 configured as described above, the presence or absence of the holding pin 30 can be visually confirmed from the first pin hole 42 communicating with the outside of the case even after assembly. On the other hand, in the structure in which the holding hole of the holding pin does not penetrate, it is impossible to visually confirm the presence or absence of the holding pin after assembly.

  In addition, in order to check the presence or absence of the holding pin even after assembly, in order to prevent the holding pin from falling off, a pin removal prevention process that caulks the differential case or pin is performed. Necessary. On the other hand, in the differential device 10 of the present embodiment, the stepped portion 46 is formed in the first pin hole 42, thereby preventing the holding pin 30 from falling off without caulking. Further, since caulking is unnecessary, each part can be reused, and disassembly and reassembly after assembly are facilitated. For example, in the past, a magnet pick was used when extracting the holding pin 30, but in this embodiment, the holding pin 30 can be pushed out from the first pin hole 42 side, so that the holding pin is not used. 30 can be removed. As a result, it is possible to avoid magnetization of the component by the magnetic pick.

  Further, since the second pin hole 44 is closed without penetrating the outside of the case, the holding pin 30 is prevented from falling off from the second pin hole 44.

  Further, since the first pin hole 42 communicates with the outside of the case, stress that tends to accumulate around the first pin hole 42 is released. Thus, even when compared with the case where the pin hole does not penetrate, the maximum stress applied around the first pin hole 42 is reduced. In addition, since caulking is not performed in this embodiment, distortion of the hole due to caulking does not occur in the first case member 14a. Therefore, the uneven stress distribution in the first case member 14a is reduced, and the stress distribution in the first case member 14a can be made uniform.

  As described above, according to the present embodiment, since the first pin hole 42 that accommodates one end of the holding pin 30 penetrates to the outside of the case, the presence or absence of the holding pin 30 can be visually confirmed even after assembly. . Further, when disassembling, the holding pin 30 can be easily taken out by pushing out the holding pin 30 from the pin hole 42 side communicating with the outside of the case. In addition, the first pin hole 42 that accommodates one end of the holding pin 30 has a smaller diameter pin hole 42b communicating with the outside of the case than the diameter of the holding pin 30, so that the holding pin 30 falls off. Is prevented.

  Next, another embodiment of the present invention will be described. In the following description, parts common to those in the above-described embodiment are denoted by the same reference numerals and description thereof is omitted.

  FIG. 3 is a sectional view of a differential device 50 according to another embodiment of the present invention. The differential device 50 is rotatably held around the axis C1 via a pair of bearings 11a and 11b in a housing 12 which is a non-rotating member. The axis C1 is a rotation axis of a side gear 20 and a drive shaft (not shown) that is spline-fitted to the side gear 20.

  The differential device 50 rotates integrally with the differential case 54 around the axis C1 by holding both ends of the differential case 54 around the axis C1 in the housing 12 via a pair of bearings 11a and 11b and the differential case 54 being held at both ends. The pinion shaft 16 that rotates, the pinion gear 18 that is rotatably fitted to the outer periphery of the pinion shaft 16, a pair of side gears 20 that mesh with the pinion shaft 18 and that can rotate about the axis C1, and a differential case by a bolt (not shown) And a ring gear 28 fixed to 54. The pinion shaft 16, the pinion gear 18, and the pair of side gears 20 constitute a differential mechanism 21, and the differential mechanism 21 is accommodated in the differential case 54.

  The differential case 54 includes two case members, a first case member 54a and a second case member 54b, and is coupled to each other by a bolt (not shown). The first case member 54a corresponds to one of the case members of the present invention.

  The first case member 54a is formed in a substantially bowl-like shape with one opening, and is supported by the bearing 11a so as to be rotatable around the axis C1. A cylindrical portion 62 into which a drive shaft (not shown) is fitted is formed on the opposite side of the opening in the axis C1 direction of the first case member 54a. A bearing 11a is provided on the outer peripheral side of the cylindrical portion 62, and the first case member 54a is rotatably supported around the axis C1 via the bearing 11a.

  The second case member 54b is formed in a disk shape, and a cylindrical portion 64 into which a drive shaft (not shown) is fitted is formed at the center portion (radially inward with the axis C1 as the center). A bearing 11b is provided on the outer peripheral side of the cylindrical portion 64, and the second case member 54b is rotatably supported around the axis C1 via the bearing 11b.

  The mating surface 66 formed on the opening side of the first case member 54a and the mating surface 68 formed on the outer peripheral side of the second case member 54b are fastened by a bolt (not shown) in contact with each other, A differential case 54 is configured. The ring gear 28 (final gear 28) is similarly fixed to the differential case 54 by bolts that fasten the first case 54a and the second case member 54b. Specifically, the second case member 54b is sandwiched between the ring gear 28 and the first case member 54a, and is fastened integrally with a bolt.

  The pinion shaft 16 has a cylindrical shape, and both ends thereof are held by the first case member 54 a of the differential case 54. Accordingly, the pinion shaft 16 is rotated around the axis C <b> 1 together with the differential case 54. The first case member 54 a is formed with a pair of through holes 70 that communicate the inside and the outside, and both ends of the pinion shaft 16 are fitted into the through holes 70. The pinion shaft 16 is fixed so as not to drop off by a holding pin 30 that penetrates the pinion shaft 16 in the radial direction.

  FIG. 4 is an enlarged cross-sectional view of the first case member 54a and the second case member 54b of FIG. 4, the alternate long and short dash line indicates the pinion shaft 16 fixed to the first case member 54a, and the alternate long and two short dashes line indicates the holding pin 30 for fixing the pinion shaft 16.

  A bolt fastening hole 72 is formed in the first case member 54a, and a bolt fastening hole 74 is also formed in the second case member 54b. The mating surface 66 of the first case member 54a and the second case member 54b are also formed. The bolts (not shown) are inserted through the bolt fastening holes 72 and the bolt fastening holes 74 in a state where the surfaces 68 are aligned.

  A through hole 70 is formed in the first case member 54a, and one end in the longitudinal direction of the pinion shaft 16 indicated by a one-dot chain line is fitted into the through hole 70. A through hole 38 that penetrates the pinion shaft 16 in the radial direction is formed in the pinion shaft 16, and a holding pin 30 indicated by a two-dot chain line is inserted through the through hole 38.

  The first case member 54a is formed with pin holes 80 that accommodate both ends of the holding pin 30 that penetrates the pinion shaft 16 in the radial direction. The pin hole 80 is formed in a longitudinal shape with a circular cross section. The pin hole 80 is formed by a first pin hole 82 that accommodates one end of the holding pin 30 and a second pin hole 84 that accommodates the other end of the holding pin 30. The first pin hole 82 corresponds to a pin hole that accommodates one end of the pin of the present invention.

  The first pin hole 82 has one end in the longitudinal direction communicating with the through hole 70 and the other end communicating with the outside of the case. That is, the first pin hole 82 penetrates to the outside of the case. The first pin hole 82 communicates with the through hole 70 and communicates with the outside of the case with a large-diameter pin hole 82a whose diameter is larger than the diameter of the holding pin 30, and the diameter of the hole is the diameter of the holding pin 30. Smaller diameter pin hole 82b. Further, a stepped portion 86 is formed between the large diameter pin hole 82a and the small diameter pin hole 82b. Thus, the first pin hole 82 is a stepped through hole having a stepped portion 86 between the large diameter pin hole 82a and the small diameter pin hole 82b.

  The holding pin 30 accommodated in the first pin hole 82 is substantially accommodated in the large-diameter pin hole 82a set to the diameter of the hole capable of accommodating the holding pin 30. Here, when the holding pin 30 moves in the large-diameter pin hole 82a in the longitudinal direction toward the small-diameter pin hole 82b, the end in the longitudinal direction of the holding pin 30 is aligned with the axis C1 formed in the stepped portion 86. Since it abuts on a vertical surface, the stepped portion 86 functions as a retaining pin 30 and prevents the retaining pin 30 from moving toward the small-diameter pin hole 82b. Accordingly, the holding pin 30 is prevented from dropping out of the case from the first pin hole 82.

  The second pin hole 84 has a diameter larger than the diameter of the holding pin 30 so that one end communicates with the through hole 70 and the holding pin 30 can be accommodated. Here, in a state where the first case member 54 a and the second case member 54 b are coupled, the protrusion 88 formed on the second case member 54 b is disposed at a position that closes the other end of the second pin hole 84. The Therefore, after assembly, the other end of the second pin hole 84 is closed by the protrusion 88 of the second case member 54b, and the second pin hole 84 becomes a non-through hole with respect to the outside of the case. This prevents the holding pin 30 accommodated in the second pin hole 84 from falling out of the case.

  In the differential device 50 configured as described above, the presence or absence of the holding pin 30 can be visually confirmed from the first pin hole 82 communicating with the outside of the case even after assembly.

  In the differential device 50 of this embodiment, the stepped portion 86 is formed in the first pin hole 82, so that the holding pin 30 is prevented from falling off without being caulked. Further, since caulking is unnecessary, each part can be reused, and disassembly and reassembly after assembly are facilitated.

  On the second pin hole 84 side, since the end of the hole is closed by the projection 88 of the second case member 54b after assembly, a part for preventing the holding pin 30 from falling off is separately provided. Without adding, it is possible to prevent the holding pin 30 from coming off from the second pin hole 84.

  As described above, also in this embodiment, the first pin hole 82 that accommodates one end of the holding pin 30 penetrates to the outside of the case, so that the presence or absence of the holding pin 30 can be visually confirmed even after assembly. Further, when disassembling, the holding pin 30 can be easily taken out by pushing out the holding pin 30 from the first pin hole 82 side communicating with the outside of the case. In addition, the first pin hole 82 that accommodates one end of the holding pin 30 has a smaller diameter pin hole 82b communicating with the outside of the case than the diameter of the holding pin 30, so that the holding pin 30 falls off. Is prevented. Further, since the second pin hole 84 that accommodates the other end of the holding pin 30 is closed by the second case member 84b after assembly, the holding pin can be removed from the second pin hole 84 without adding additional components. 30 is prevented from falling off.

  As mentioned above, although the Example of this invention was described in detail based on drawing, this invention is applied also in another aspect.

  For example, in the above-described embodiment, the surface perpendicular to the axis C1 is formed in the first pin holes 42 and 82 by the stepped portions 46 and 86, but is not necessarily limited to the vertical surface. It may be changed in a tapered shape.

  In the above-described embodiment, the differential devices 10 and 50 include the two pinion gears 18. However, the differential devices 10 and 50 may include three or more pinion gears. Note that the shape of the pinion shaft is appropriately changed according to the number of pinion gears.

  The above description is only an embodiment, and the present invention can be implemented in variously modified and improved forms based on the knowledge of those skilled in the art.

10, 50: differential device 14, 54: differential case 14a, 54a: first case member (one of case members)
16: Pinion shaft 18: Pinion gear 20: Side gear 21: Differential mechanism 26, 70: Through hole 30: Holding pin (pin)
40, 80: Pin hole 42, 82: First pin hole (pin hole on the side that accommodates one end of the pin)

Claims (1)

A differential mechanism that includes a pinion shaft, a pinion gear that is rotatably fitted to the outer periphery of the pinion shaft, and a pair of side gears that mesh with the pinion gear, and two case members. A differential device including a differential case to be housed,
In one of the case members, a through hole into which the pinion shaft is fitted is formed, and a pin hole that accommodates both ends of a pin that penetrates the pinion shaft in the radial direction is formed,
The pin hole on the side that accommodates one end of the pin communicates with the outside of the case, and the diameter of the hole on the side that communicates with the through hole in the longitudinal direction is larger than the diameter of the pin. A differential device, wherein a diameter of a hole on a side communicating with the outside of the case is smaller than a diameter of the pin.

Images