JP4858513B2 - Method of joining differential device and joining aid - Google Patents

Description

  The present invention relates to a technique for joining a ring gear by welding to a differential case.

A differential gear used in a driving mechanism of an automobile is one of differential devices that are used in a shaft that connects driving wheels of an automobile and absorbs a speed difference between an inner ring and an outer ring when the automobile is curved.
Briefly describing the structure, the differential gear includes a ring gear held outside the differential case, a pinion gear provided inside the differential case and attached to the differential case, and a gear attached to an axle meshing with the pinion gear.
A driving force generated by an automobile engine or the like is transmitted to a ring gear joined to the differential case, and power is transmitted to the axle by rotating a gear attached to the axle by a pinion gear attached to the differential case.

In addition, there is a differential gear used for automobiles that compensates for the disadvantage of the differential gear that causes the axle to idle when one of the wheels called LSD is unloaded, but a ring gear is provided outside the differential case. The structure is the same in terms of use.
As a method of joining the ring gear to the differential case provided in the differential device, a method of fastening using a bolt has been conventionally employed.
However, when this bolt fastening method is used, there is a problem that the weight increases because the weight of the bolt and the thickness necessary for fastening with the bolt are required.

Therefore, a method that does not use bolts to join the differential case and the differential gear is also being studied.
Patent Document 1 discloses an invention of a friction welding member and a differential device including the same.
The differential case and the ring gear are each provided with a pressure contact portion that comes into contact with the surface, and the pressure contact portion is heated by frictional heat by causing the ring gear to rotate with respect to the differential case so that the pressure contact portions contact each other. They are friction welded together. Thus, since the differential case and the ring gear are integrated, it is not necessary to fasten with a bolt, and the weight can be reduced.

Patent Document 2 discloses an invention relating to a torque transmission member joining structure, a torque transmission member joining method, and a power transmission device using these.
The structure is such that a carburized steel ring gear and an FCD differential case are joined by performing CMT welding using a welding wire. By doing so, the power transmitted to the ring gear can be transmitted to the differential case. Further, by welding, it is not necessary to fasten with bolts, and the weight can be reduced.

JP 2005-81351 A JP 2007-170622 A

However, Patent Literature 1 and Patent Literature 2 are considered to have the following problems.
In both Patent Document 1 and Patent Document 2, a technique of welding a ring gear to a differential case is used. However, in Patent Document 1, it is necessary to process the surface of the pressure contact portion in order to ensure strength when performing friction welding. For this reason, it is considered that it is difficult to make friction welding evenly if the ring gear is not evenly applied to the differential case and rotated accurately with friction welding.
Moreover, in patent document 2, although the ring gear and the differential case are joined by performing CMT welding, a technique for increasing the welding accuracy is not specifically mentioned.

  When the differential case and the ring gear are welded, the differential case after welding needs to rotate without shaking. Since the deflection of the differential case affects the quietness and vibration of the automobile, the life of the differential gear, etc., it is desirable that the deflection be minimized.

  Therefore, in order to solve such a problem, the present invention has an object to provide a method of joining a differential device and a joining aid capable of improving welding accuracy in welding of a differential case and a ring gear. .

In order to achieve the above object, a method for joining differential devices according to the present invention has the following characteristics.
(1) The ring gear press-fitted to the position of the flange portion of the differential case is sandwiched between the ring gear guide inserted from the opposite side of the flange portion and the flange portion, and these are interposed via a thrust bearing and a radial bearing. The ring case is clamped by a pair of clamping members from both axial sides of the differential case, and one of the pair of clamping members is fixed to a predetermined processing facility, and the other side of the pair of clamping members is pressurized in the axial direction, and the ring gear And the differential case are welded while rotating at a constant speed.

(2) In the method for joining differential devices according to (1),
The pair of clamping members includes a pressing jig and a holding jig, and a connecting member for connecting the pressing jig and the holding jig, and the pair of clamping members sandwich the differential case and the ring gear. Then, the ring gear and the differential case are welded while pressurizing the flange portion of the differential case by a pressurizing means provided in the pressing jig.

Moreover, in order to achieve the said objective, the joining auxiliary tool by this invention has the following characteristics.
(3) The pair of clamping members that hold the differential case includes a pressing jig and a holding jig,
The pressing jig includes a pressing means for pressing the differential case, and a case pressing member for uniformly transmitting the pressing force of the pressing means to the flange portion of the differential case,
The holding jig has a ring gear guide that receives the differential case,
The differential case and a ring gear inserted in contact with the flange portion on the outer periphery of the differential case are clamped by the pair of clamping members from both axial sides of the differential case via a thrust bearing and a radial bearing. To do.

The following operations and effects can be obtained by the method of joining a differential device according to the present invention having such characteristics.
First, in the invention described in (1), the ring gear press-fitted to the position of the flange portion of the differential case is thrust between the ring gear guide inserted from the opposite side of the flange portion and the flange portion. A pair of clamping members are clamped from both sides in the axial direction of the differential case via bearings and radial bearings, and one of the pair of clamping members is fixed to a predetermined processing facility and pressurized from the other side of the pair of clamping members in the axial direction. The ring gear and the differential case are welded while rotating at a constant speed.

When the ring gear press-fitted to the position of the flange portion of the differential case is welded, the ring gear guide and the flange portion are clamped by a pair of clamping members.
Since the pair of clamping members are provided with a thrust bearing and a radial bearing, the differential case and the ring gear are rotated at a constant speed while maintaining coaxiality, and can be precisely welded.
When welding with a processing facility, for example, when beam welding is used, the focal length is important. Therefore, by rotating the flange portion of the differential case and the outer peripheral portion of the contact surface of the ring gear while maintaining the coaxiality, it is possible to increase welding accuracy and contribute to the reduction of welding failure.

Next, the invention described in (2) is the method of joining the differential device according to (1), wherein the pair of clamping members are a pressing jig, a holding jig, and a pressing jig and a holding jig. And connecting the ring gear and the differential case while pressing the flange portion of the differential case with the pressurizing means provided in the pressing jig after the differential case and the ring gear are clamped by the pair of clamping members. Is.
By receiving the ring gear with the ring gear guide and welding while pressing the flange portion of the differential case with the pressurizing means, the welding accuracy can be improved.

Moreover, the following operation | movement and an effect are acquired by the joining auxiliary tool by this invention which has such a characteristic.
First, in the invention described in (3), the pair of holding members that hold the differential case includes a pressing jig and a holding jig, and the pressing jig includes a pressing unit that pressurizes the differential case, A holding member for uniformly transmitting the pressing force of the pressure means to the flange portion of the differential case, and the holding jig has a ring gear guide for receiving the differential case, and is in contact with the flange portion on the outer periphery of the differential case and the differential case The ring gear inserted in this manner is clamped by a pair of clamping members from both axial sides of the differential case via a thrust bearing and a radial bearing.
By sandwiching and welding the differential case and the ring gear using such a joining jig, it is possible to increase the welding accuracy between the differential case and the ring gear, and to contribute to the reduction of welding float.

First, the configuration of the embodiment of the present invention will be described.
FIG. 1 shows a schematic cross-sectional view of the differential case and the ring gear of the present embodiment.
The differential case 10 is a case of a differential 15 used in an automobile, and is made by casting aluminum or iron as a material. A first bearing connection portion 10 a and a second bearing connection portion 10 b are formed at the end of the differential case 10, and a flange portion 10 c is formed at the outer periphery of the differential case 10. The first bearing connecting portion 10a and the second bearing connecting portion 10b are precisely machined so as to have a coaxial degree because a bearing for supporting the differential case 10 is fitted, and this outer peripheral portion is used as a reference surface of the differential case 10. Yes.

A ring gear 11 is attached so as to abut on a flange portion 10c formed on the differential case 10. The ring gear 11 is a bevel gear, and the differential case 10 and the ring gear 11 are joined by welding with the contact surface 11a of the ring gear 11 in contact with the flange contact surface 10d. The ring gear 11 is formed with a tooth portion 11b to transmit the power of the automobile.
Note that the differential device 15 shown in FIG. 1 omits gears inside the differential device 15 for the purpose of simplification. Therefore, although the cross section of the differential case 10 is actually different from that in FIG. 1, in this embodiment, only the relationship between the differential case 10 and the ring gear 11 needs to be known, so this is expressed.

FIG. 2 shows an enlarged view of a joint portion between the differential case and the ring gear. It is an enlarged view of the part A shown in FIG.
The differential case 10 and the ring gear 11 are joined by laser welding in a state where the flange contact surface 10d and the contact surface 11a contact each other and the case fitting portion 10e and the gear fitting portion 11c are engaged. Therefore, the welded portion 12 is formed in a state of straddling the contact surface between the flange portion contact surface 10d and the contact surface 11a.
By welding the differential case 10 and the ring gear 11 in this way, it is possible to reduce the weight of the differential device 15 as compared with a case where the differential case 10 and the ring gear 11 are coupled with each other. When bolts are used to fasten the differential case 10 and the ring gear 11, it is necessary to form screw holes for stopping the bolts. Therefore, it is necessary to make the differential case 10 and the ring gear 11 thick. Since there is no need to use bolts, the weight can be reduced.

FIG. 3 shows a cross-sectional view of the welding jig.
FIG. 4 is a cross-sectional view showing a state where the welding jig and the differential case are disassembled.
A welding jig 20 serving as a joining aid includes a pressing jig 21, a connection post 22, and a holding jig 23. The connection post 22, which is a connection member for connecting the pressing jig 21 and the holding jig 23, has screw holes on both sides, and is fixed to the pressing jig 21 and the holding jig 23 with bolts.
A rotation holding member 25 is attached to the holding jig 23 via a thrust bearing 41 and a radial bearing 42. About the thrust bearing 41 and the radial bearing 42, those with high accuracy applied with preload are used.
The holding jig 23 is attached to the connection boss 28, and the welding jig 20 is connected to the rotary table 51 through the connection boss 28. The rotary table 51 is provided in the rotating device 50 and is configured to be rotatable at a constant speed. The rotation holding member 25 and the connection boss 28 are configured such that a pin 29 is driven and rotates together.

A ring gear guide 24 is attached to the rotation holding member 25. The rotation holding member 25 is provided with a first holding hole 25a. The first holding hole 25a is a hole into which the first bearing connecting portion 10a of the differential case 10 is inserted. The 1st bearing connection part 10a and the 1st holding hole 25a become a dimension which can be fitted.
The ring gear guide 24 is a cylindrical member and is shaped to receive the ring gear 11 by its surface.

A pressing bolt 30 is inserted into the pressing jig 21. The pressing bolt 30 can pressurize the case upper pressing jig 26 and the pressure receiving member 27 because the screw groove is cut in the pressing jig 21.
The case upper pressing jig 26 and the pressure receiving member 27 are fixed via the thrust bearing 41 and the thrust bearing 41, and the second bearing connecting portion of the differential case 10 is provided by the second holding hole 26 a provided in the case upper pressing jig 26. It is a mechanism for holding 10b.
The case upper pressing jig 26 is provided with a plurality of pressurizing bolts 31, and the pressurizing force of the pressing bolt 30 is mainly transmitted to the differential case 10 by the pressurizing bolt 31. The pressurizing bolt 31 presses the flange portion 10 c of the differential case 10 and is disposed on an extension line of the ring gear guide 24.

An important point in designing the welding jig 20 is that the rotation center of the differential case 10 coincides with the rotation center CL of the welding jig 20. Therefore, the center of the first holding hole 25a of the rotation holding member 25 and the second holding hole 26a of the case upper pressing jig 26 is designed to coincide with the rotation center CL.
In FIG. 5, the schematic diagram of a welding apparatus is shown.
The welding device 60 includes a rotation device 50, a welding jig 20 attached thereto, and a laser welding device 52.
The rotating device 50 has a function of rotating the rotary table 51 at a constant speed, and can rotate the differential case 10 and the ring gear 11 at a constant speed with the welding jig 20 attached. It is preferable to prepare a rotation speed whose setting can be changed.

The laser welding device 52 is a laser welding head, and details thereof are omitted. In the experiment of the present invention, a YAG laser was used, but the present invention is not limited to this. If necessary, another type of laser may be used, or electron beam welding may be employed.
In addition to laser welding, the applicant has tried joining methods such as electron beam welding, arc welding, FSW, brazing, etc., but since laser welding has obtained the best results, laser welding was performed in the examples. The example used is introduced.

Since the present embodiment has the above-described configuration, the following operation is exhibited.
First, the ring gear 11 is assembled to the differential case 10. The ring gear 11 is formed so that the inner diameter of the gear fitting portion 11c is smaller than the outer diameter of the case fitting portion 10e of the differential case 10, so that the ring gear 11 is fitted to the differential case 10 in an interference fit state.
Thereafter, the differential case 10 is fixed to the welding jig 20 as shown in FIG. In a state where the differential case 10 is fixed to the welding jig 20, the pressing bolt 30 is tightened, and the flange portion 10 c of the differential case 10 is uniformly pressed by the pressurizing bolt 31. As a result, the flange portion 10 c and the ring gear 11 are sandwiched between the pressure bolt 31 and the ring gear guide 24.

The pressure applied to the flange portion 10c by the pressure bolt 31 is set to about 2t. In addition, although the pressurizing force which can be pressurized with the press volt | bolt 30 is about 0-10t, you may change suitably.
The tip portions of the first bearing connection portion 10a and the second bearing connection portion 10b of the differential case 10 do not contact the second holding hole 26a of the case upper pressing jig 26 and the first holding hole 25a of the rotation holding member 25, respectively. Since a clearance of about several millimeters is provided, the flange contact surface 10d and the contact surface 11a come into contact with each other in a pressurized state.
Therefore, the pair of clamping members includes a case upper pressing jig 26 provided in the pressing jig 21 and a pressure bolt 31 provided therein, and a rotation holding member 25 and a ring gear guide 24 provided in the holding jig 23. The differential case 10 and the ring gear 11 are supported.

Thus, 10 and the ring gear 11 are held by the welding jig 20 and are rotated at a constant speed by the rotating device 50. In this state, the differential case 10 and the ring gear 11 are welded by the laser welding device 52.
When the rotary table 51 is rotated at a constant speed by a rotating device 50 at a low speed of about several rpm, the rotary holding member 25 connected to the rotary table 51, the ring gear guide 24 connected to the rotary holding member 25, and the pressure receiving member The case upper pressing jig 26 rotatably held by the rotor 27 is rotated, and the differential case 10 and the ring gear 11 are rotated accordingly.
On the other hand, a rotational force is not directly transmitted to the pressing jig 21, the connection post 22, and the holding jig 23, but a slight force is transmitted via the thrust bearing 41 and the radial bearing 42. However, since the laser is irradiated at one point by the fixed laser welding apparatus 52, a stay (not shown) is provided in the pressing jig 21 or the holding jig 23 so that the connection post 22 does not cross the laser welding apparatus 52. It is fixed so that it does not rotate.
In this way, the differential case 10 and the ring gear 11 are integrated by laser welding.

Since this embodiment exhibits the above-described operation with the above-described configuration, the following effects can be obtained.
First, the first effect is that the welding accuracy between the ring gear 11 and the differential case 10 can be improved.
In the joining method of the differential device 15 of the present embodiment, the ring gear 11 press-fitted to the position of the flange portion 10c of the differential case 10 is sandwiched between the ring gear guide 24 inserted from the opposite side of the flange portion 10c and the flange portion 10c. In this state, they are clamped by a pair of clamping members (welding jig 20 including the pressing jig 21 and the holding jig 23) from both sides in the axial direction of the differential case 10 via the thrust bearing 41 and the radial bearing 42. In addition to fixing one of the clamping members to a predetermined processing facility, pressure is applied in the axial direction from the other side of the pair of clamping members, and welding is performed while rotating the ring gear 11 and the differential case 10 at a constant speed.

Since the welding jig 20 uses a thrust bearing 41 and a radial bearing 42 to support the rotation of the case upper pressing jig 26 and the rotation holding member 25, the differential case 10 can be used if the processing accuracy of the welding jig 20 is high. It can be rotated without touching.
The applicant also conducted an experiment using an angular bearing instead of the thrust bearing 41 and the radial bearing 42. However, it has been found that when the differential device 15 is welded using an angular bearing, the deflection of the outer periphery of the ring gear 11 increases after the differential device 15 is welded. This means that it is not easy to obtain the coaxiality of the differential case 10 and the ring gear 11 as compared with the case where the angular bearing uses the thrust bearing 41 and the radial bearing 42.
When welding with the laser welding device 52, the focal length of the laser is important. Ideally, the focal point of the laser welding device 52 moves on the outer periphery of the contact surface between the differential case 10 and the ring gear 11, and if a blur occurs, the welding depth cannot be ensured and a welding failure may occur. is there.

When joining the differential case 10 and the ring gear 11, since it is a component to which vibration and heat are applied after being mounted on the vehicle, certainty of joining is required. In addition, if the distortion is generated in a biased manner during welding, it may cause a joint failure and may cause an eccentricity.
However, since the differential case 10 and the ring gear 11 are rotated using the thrust bearing 41 and the radial bearing 42, the differential case 10 and the ring gear 11 can be rotated while ensuring 360 ° coaxiality. Further, by rotating at a constant speed using the rotary table 51, heat is uniformly received from the outer peripheral sides of the contact surfaces of the flange contact surface 10d and the contact surface 11a. It becomes possible to suppress the factor of the fluctuation.

Further, in the method of joining the differential device according to the present embodiment, the pair of clamping members are connected to connect the pressing jig 21 and the holding jig 23 and the pressing jig 21 and the holding jig 23 in order to increase the welding accuracy. The post gear 22 and the pair of clamping members sandwich the differential case 10 and the ring gear 11, and then press the flange 10 c of the differential case 10 with the pressing bolt 30 provided in the pressing jig 21, The structure which welds the differential case 10 is taken.
For this reason, the flange portion 10c of the differential case 10 in a state in which the ring gear 11 is sandwiched between the ring gear guide 24 and the flange portion 10c, that is, in a state in which the ring gear 11 is press-fitted with the pressurizing bolt 31, is applied in the direction of the ring gear guide 24. Since welding is performed by the laser welding device 52 in a pressed state, welding is performed in a state in which the flange contact surface 10d of the flange portion 10c and the contact surface 11a of the ring gear 11 are in contact.

Since the flange contact surface 10d and the contact surface 11a are in contact with each other in a pressurized state, unnecessary gaps can be prevented when welding with the laser welding device 52, and welding accuracy is improved. It becomes possible.
Moreover, since the same state as the state which fastened the differential case 10 and the ring gear 11 with the volt | bolt can be created, the manufacture precision of the differential device 15 can be improved.

Although the invention has been described according to the present embodiment, the invention is not limited to the embodiment, and by appropriately changing a part of the configuration without departing from the spirit of the invention. It can also be implemented.
For example, since the change of a fine part such as the shape of the welding jig 20 is a design matter, the change is not prevented as appropriate.
Also, the welding method is not particularly limited to laser welding. In addition to laser welding, the applicant tried and evaluated joining methods such as electron beam welding, arc welding, FSW, and brazing. As a result, laser welding was good except for the cost. In addition, arc welding shows relatively good results. Since the welding jig 20 of the present invention can be used not only for laser welding but also for other welding methods, it does not hinder it.

  Further, in the present embodiment, an example in which the flange portion 10c of the differential case 10 is pressed by the pressing bolt 30 has been shown, but it is also possible to apply pressure using a ball screw mechanism or the like by hydraulic pressure, air pressure, motor drive, or the like. Such a change of the pressure mechanism to the differential case 10 and the ring gear 11 is not disturbed.

It is a schematic sectional drawing of a differential case and a ring gear of this embodiment. It is an expanded sectional view of the junction part of a differential case and a ring gear of this embodiment. It is sectional drawing of the welding jig | tool of this embodiment. It is sectional drawing showing a mode that the welding jig and differential case of this embodiment were decomposed | disassembled. It is a schematic diagram of the welding apparatus of this embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Differential case 10a 1st bearing connection part 10b 2nd bearing connection part 10c Flange part 10d Flange part contact surface 10e Case fitting part 11 Ring gear 11a Contact surface 11b Tooth part 11c Gear fitting part 12 Welding part 15 Differential device 20 welding jig 21 pressing jig 22 connection post 23 holding jig 24 ring gear guide 25 rotation holding member 25a first holding hole 26 case upper pressing jig 26a second holding hole 27 pressure receiving member 28 connecting boss 29 pin 30 pressing bolt 31 Pressurizing bolt 41 Thrust bearing 42 Radial bearing 50 Rotating device 51 Rotating table 52 Laser welding device 60 Welding device CL Center of rotation

Claims (3)

In a state where the ring gear press-fitted to the position of the flange portion of the differential case is sandwiched between the ring gear guide inserted from the opposite side of the flange portion and the flange portion,
They are sandwiched by a pair of clamping members from both axial sides of the differential case via a thrust bearing and a radial bearing,
While fixing one of the pair of clamping members to a predetermined processing facility, pressurize in the axial direction from the other side of the pair of clamping members,
The differential gear joining method, wherein the ring gear and the differential case are welded while rotating at a constant speed. The method for joining differential devices according to claim 1,
The pair of clamping members includes a pressing jig and a holding jig, and a connecting member for connecting the pressing jig and the holding jig,
After sandwiching the differential case and the ring gear with the pair of clamping members,
The differential gear joining method, wherein the ring gear and the differential case are welded while pressurizing the flange portion of the differential case by a pressurizing means provided in the pressing jig. The pair of clamping members that hold the differential case includes a pressing jig and a holding jig,
The pressing jig includes a pressing means for pressing the differential case, and a case pressing member for uniformly transmitting the pressing force of the pressing means to the flange portion of the differential case,
The holding jig has a ring gear guide that receives the differential case,
The differential case and a ring gear inserted so as to be in contact with the flange on the outer periphery of the differential case are clamped by the pair of clamping members from both axial sides of the differential case via a thrust bearing and a radial bearing. Joining aid to do.

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