JP2000199016A - Induction hardening device of constant-velocity universal joint - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve the induction hardening of a cup part and a shaft part of a constant-velocity universal joint at the same position. SOLUTION: An induction hardening device to achieve the induction hardening of a cup part WC and a shaft part WS of a constant-velocity universal joint W without moving the joint W in which the cup part WC with six grooves formed therein is integratedly formed with the shaft part WS projected from the cup part WC, is provided with an induction hardening coil 500 for the cup part to be arranged inside the cup part WC, a jacket 550 for the cup part to inject a hardening liquid L against an inner side of the cup part WC, an outer circumferential jacket 270 to inject the hardening liquid L against the cup part WC from its outer side, a hardening coil 600 for shaft part to be arranged around the shaft part WS, a jacket 660 for the shaft part to inject the hardening liquid L against the shaft part WS, and a work placement table 700 to turn the constant-velocity universal joint W placed thereon, the outer circumferential jacket 270 is formed of approximate U-shape, and the hardening coil 600 for the shaft part heats the shaft part WS from an opening 271 side of the outer circumferential jacket 270.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a constant velocity joint in which induction hardening is performed without moving the constant velocity joint at the same place in a cup portion and a shaft portion of a constant velocity joint used in a traveling system of an automobile or the like. To an induction hardening device.

[0002]

2. Description of the Related Art A constant velocity joint comprises a cup having a groove formed on an inner surface thereof and a shaft protruding from the cup. In such a constant velocity joint, induction hardening is performed on the inner surface of the cup portion and the surface of the shaft portion.

[0003] This induction quenching includes a quenching coil for a cup portion for high-frequency heating on an inner surface of the cup portion, a jacket for a quench portion for injecting a quenching liquid on the inner surface side of the cup portion, and It has an outer peripheral jacket for injecting a quenching liquid, a quenching coil for a shaft section for high-frequency heating the shaft section, and a jacket for a shaft section for injecting a quench liquid to the shaft section.

In this kind of conventional induction hardening device for a constant velocity joint, when the induction hardening of the shaft portion is completed, the constant velocity joint is moved from a position where the hardening coil for the shaft portion is located to the hardening portion for the cup portion. Induction quenching of the cup part is performed by moving to the position where the input coil is located.

[0005] The induction hardening of the cup portion and the induction hardening of the shaft portion are performed at different positions in the constant velocity joint for the following reasons.

The outer jacket has a substantially cylindrical shape,
The cup is covered from the outside. In addition, the outer jacket is designed to prevent heat from being transmitted from the cup portion to the shaft portion that has been subjected to the induction hardening at the time of heating the cup portion. In order to reduce the distortion of the cup portion, the quenching liquid is also injected at the boundary between the cup portion and the shaft portion. Therefore, the upper end of the outer jacket reaches the shaft portion. That is, the outer jacket is formed taller than the cup portion. Therefore, the shaft portion hardening coil for heating the shaft portion cannot be provided at a position where the shaft portion is heated because the outer peripheral jacket is in the way.
For this reason, induction hardening is performed on the shaft portion and then on the cup portion. Alternatively, after induction hardening is performed on the cup portion, induction hardening is performed on the shaft portion at another position.

[0007]

As described above, if induction hardening of the shaft portion and induction hardening of the cup portion are performed at different positions, it is necessary to move the constant velocity joint, and at each position. Since the positioning of the constant velocity joint is required, the production efficiency has a certain limit. In addition, a large space for installing the induction hardening device is required. Furthermore, since the cup portion and the shaft portion are quenched at different and separate positions, there is a certain limit in cost reduction.

The present invention has been made in view of the above circumstances, and it is possible to perform induction hardening at the same position with respect to a cup portion and a shaft portion of a constant velocity joint without moving the constant velocity joint. An object is to provide an induction hardening device for a constant velocity joint.

[0009]

According to the present invention, there is provided an induction hardening apparatus for a constant velocity joint according to the present invention, wherein a cup part and a shaft part of a constant velocity joint are integrally formed with a cup part and a shaft part protruding from the cup part. And an induction hardening device for induction hardening without moving the constant velocity joint,
A hardening coil for the cup portion arranged inside the cup portion,
A jacket for the cup portion for injecting the quenching liquid on the inner surface of the cup portion, an outer peripheral jacket for injecting the quenching solution from the outside to the cup portion, a quenching coil for the shaft portion disposed around the shaft portion, and a shaft. A shaft portion jacket for injecting a quenching liquid into the portion, and a work mounting table for rotatingly driving the mounted constant velocity joint, and the outer peripheral jacket is formed in a substantially U-shape. The quenching coil heats the shaft from the open side of the outer jacket.

[0010]

FIG. 1 is a schematic front view of an induction hardening device for a constant velocity joint according to an embodiment of the present invention.
1 is a schematic plan view of an induction hardening device for a constant velocity joint according to an embodiment of the present invention, and FIG. 3 is a hardening for a cup portion used in the induction hardening device for a constant velocity joint according to the embodiment of the present invention. FIG. 4 is a schematic perspective view of the coil, FIG. 4 is a schematic perspective view of a shaft hardening coil used in the induction hardening device for the constant velocity joint according to the embodiment of the present invention, and FIG. 5 is an embodiment of the present invention. 6 is a timing chart illustrating the operation of the induction hardening device for a constant velocity joint according to the first embodiment.

An induction hardening apparatus for a constant velocity joint according to an embodiment of the present invention has a cup W having six grooves formed therein.
C and a shaft portion WS protruding from the cup portion WC are integrally formed. An induction hardening device for induction hardening the cup portion WC and the shaft portion WS of the constant velocity joint W, the inside of the cup portion WC. , A quenching coil 500 for injecting the quenching liquid L to the inner surface of the cup WC, and an outer jacket 270 for injecting the quenching liquid L to the cup WC from the outside. , A quenching coil 600 for the shaft disposed around the shaft WS, a shaft 660 for injecting the quenching liquid L to the shaft WS, and a work for rotating the mounted constant velocity joint W. And a mounting table 700,
The outer peripheral jacket 270 is formed in a substantially U shape, and the quenched coil 600 for the shaft portion is
The shaft portion WS is heated from the opening 271 side of the shaft 70.

The quenching coil 500 for the cup portion is shown in FIG.
As shown in FIG. 3, a power supply conductor 510 and a spiral heating conductor 520 having both ends connected to the power supply conductor 510 are provided. One power supply conductor 510
Pass through the inside of the heating conductor 520. The diameter of the heating conductor 520 is set slightly smaller than the inner diameter of the cup WC.

The quenching coil 500 for the cup portion is formed by bending a hollow square pipe, so that a coolant flows through the inside.

At the center of the quenching coil 500 for the cup, that is, at the center of the heating conductor 520, a jacket 550 for the quenching liquid L is sprayed onto the inner surface of the cup WC. The tip of the jacket 550 for the cup portion is an injection hole 551 for injecting the quenching liquid L. Since the jacket 550 for the cup is inserted into the cup WC such that the injection hole 551 faces the bottom of the cup WC, the quenching liquid L injected from the cup WC is inserted into the cup WC.
Is poured over the entire inner surface of the cup WC.

On the other hand, the quenching coil 600 for the shaft portion
As shown in FIGS. 1 and 4, a semiconductor open saddle type quenched coil is used. That is, a pair of power supply conductors 610, a pair of substantially arc-shaped first arc-shaped conductors 620 connected to the power supply conductor 610, respectively, and a pair of power supply conductors 610 connected to the first arc-shaped conductor 620, respectively. A heating conductor 630;
A second arc-shaped conductor 640 having a substantially half-arc shape for connecting the heating conductor 630 is provided.

Each of the conductors 610, 620, 630, 640 of the hardened coil 600 for a shaft portion is formed of a hollow pipe, through which a cooling liquid flows. Accordingly, the coolant is supplied to one of the power supply conductors 610 → the one first arc-shaped conductor 620 → the one heating conductor 630 → the second arc-shaped conductor 640 → the other heating conductor 630 → the other first arc-shaped conductor. 620 → the other power supply conductor 610.

The shaft portion jacket 660 injects the quenching liquid L to the shaft portion WS, and is disposed on both sides of the shaft portion quenching coil 600. In addition, the shaft portion jacket 660 is located at a position slightly higher than the shaft portion WS, and is configured to inject the quenching liquid L obliquely downward.

An outer jacket 270 is provided around the cup WC. This outer jacket 2
70 is for preventing overheating at the time of heating of the cup part WC. The outer peripheral jacket 270 is formed in a substantially U shape in plan view. That is, one of the outer jackets 270 is open.

Further, the height of the outer peripheral jacket 270 is set obliquely lower to prevent the heat of the cup portion WC from being transmitted to the shaft portion WS, to improve the flow of the quenching liquid L, and to uniformly cool the shaft portion WS. Therefore, the height is set slightly higher than the height of the cup WC. Therefore, a part of the quenching liquid L injected from the outer peripheral jacket 270 is also injected to the base end side of the shaft portion WS.

The quenching liquid L sprayed from the outer peripheral jacket 270 strikes the outer peripheral surface of the cup portion slightly downward.

The work mounting table 700 mounts a constant velocity joint W as a work. The work mounting table 700 includes a turntable 710 having an opening 711 through which the quench coil 500 for the cup portion and the jacket 550 for the cup portion pass, and a bearing 720 provided on the lower surface side of the turntable 710. It has a fixed base 730 that receives the bearing 720, an output gear 820 that meshes with a gear 713 provided at the edge of the rotary base 710, and a drive unit 810 that drives the output gear 820 to rotate. Therefore, the turntable 710 is rotatable.

A ring-shaped insulating spacer 712 is provided so as to surround the opening 711 of the turntable 710. On this spacer 712, a constant velocity joint W
By placing the lower end portion of the cup portion WC of
The constant velocity joint W is mounted on the work mounting table 700. The work mounting table 700 also plays a role of concentrating when the constant velocity joint W is overheated (that is, a role of preventing the lower end portion of the constant velocity joint W from being heated). Further, a fixing jig 714 for fixing the constant velocity joint W is provided outside the spacer 712.

The fixing base 730 has an opening 731 through which the hardened coil 500 for the cup portion and the jacket 550 for the cup portion can pass.

Accordingly, the constant velocity joint W supporting the shaft portion WS at the work center 830 is
As a result, it rotates with the turntable 710. The drive section 810 can change the rotation when the shaft section WS and the cup section WC are quenched by the inverter motor.

Next, the induction hardening operation by the induction hardening device for a constant velocity joint as described above will be described.

First, the constant velocity joint W is transferred onto the work mounting table 700 by a work loading device (not shown). Then, the hardened coil for the cup portion 500 is inserted into the inner peripheral surface of the cup portion WC, and the hardened coil for the shaft portion 600 is arranged around the shaft portion WS. The lower end of the cup WC of the constant velocity joint W is mounted on the spacer 712. Also, during this work,
The constant velocity joint W is rotated by the work mounting table 700.

In this state, the quenching coil 60 for the shaft is
0 is supplied from the current transformer 900 for the shaft portion via the output terminal 910 to heat the shaft portion WS. At this time, the quenching coil 600 for the shaft portion is slid and set from the opening 371 side of the outer peripheral jacket 270, so that the height of the outer peripheral jacket 270 is set to the cup portion WC.
Even if it is slightly higher than the height of the shaft,
A value of 0 can reliably heat the shaft portion WS.

The quenching liquid L may or may not be injected from the outer jacket 270 to the outer peripheral surface of the cup WC at the same time as the heating of the shaft WS is started. This is appropriately changed according to the specifications required for the constant velocity joint W.

The heating of the shaft portion WS is completed (T ₂ ).
At the same time, the quenching liquid L is injected from the shaft portion jacket 660 to cool the shaft portion WS, and the shaft portion WS
To induction hardening.

Further, simultaneously with the cooling of the shaft portion WS, it starts supplying current through an output terminal 940 from the cup portion for current transformer 930 to the cup portion for hardening the coil 500 from the predetermined time T _2.

[0031] When an electric current to the cup portion for hardening the coil 500 is supplied to a predetermined time T _3, power supply to the cup portion for hardening the coil 500 is stopped. At the same time, the quenching liquid L is injected from the cup jacket 550, and induction hardening of the cup WC is performed. At this point (T ₃ )
The injection of the quenching solution L from the shaft portion jacket 660 is continued, and the quenching solution L from the cup portion jacket 550 is continued.
During the injection (T ₄ ), the shaft portion jacket 6
The injection of the quenching liquid L from 60 ends.

Further, after the injection of the quenching liquid L from the shaft portion jacket 660 ends, at time T ₅ ,
The injection of the quenching liquid L from the outer jacket 270 ends.

Thereafter, the constant velocity joint W is unloaded by a work unloading device (not shown), the next new constant velocity joint W is loaded by the work loading device, and induction hardening is performed in the same cycle. The quenching liquid L from the cup jacket 500 is discharged to the outside via the openings 711 and 731.

[0034]

According to the induction hardening apparatus for a constant velocity joint according to the present invention, the cup and the shaft of the constant velocity joint in which the cup and the shaft protruding from the cup are integrally formed are formed at a constant velocity. An induction hardening device for induction hardening without moving a joint, wherein a hardening coil for the cup portion is disposed inside the cup portion and a jacket for the cup portion for injecting a quenching liquid onto the inner surface of the cup portion. And, an outer peripheral jacket that injects a quenching liquid from outside to the cup portion, and a quenching coil for the shaft portion arranged around the shaft portion,
A shaft portion jacket for injecting the quenching liquid onto the shaft portion, and a work mounting table for rotatingly driving the mounted constant velocity joint; the outer peripheral jacket is formed in a substantially U-shape; The quenching coil heats the shaft from the open side of the outer jacket.

Therefore, according to the induction hardening device for a constant velocity joint, the induction hardening of the shaft portion and the induction hardening of the cup portion can be performed without moving at the same position. Since it is not necessary to move the speed joints and to position the constant velocity joints at the respective positions, it is possible to further improve the production efficiency.
In addition, the installation space for the induction hardening device can be reduced, and the effect of contributing to cost reduction can be obtained.

[Brief description of the drawings]

FIG. 1 is a schematic front view of an induction hardening device for a constant velocity joint according to an embodiment of the present invention.

FIG. 2 is a schematic plan view of an induction hardening device for a constant velocity joint according to the embodiment of the present invention.

FIG. 3 is a schematic perspective view of a cup hardening coil used in the induction hardening device for the constant velocity joint according to the embodiment of the present invention.

FIG. 4 is a schematic perspective view of a shaft hardening coil used in the induction hardening device for a constant velocity joint according to the embodiment of the present invention.

FIG. 5 is a timing chart illustrating an operation of the induction hardening device for the constant velocity joint according to the embodiment of the present invention.

[Explanation of symbols]

 270 Outer peripheral jacket 500 Hardened coil for cup part 550 Jacket for cup part 600 Hardened coil for shaft part 660 Jacket for shaft part W Constant velocity joint WS Shaft part WC Cup part

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H05B 6/10 331 H05B 6/10 331

Claims (1)

[Claims] An induction hardening apparatus for induction hardening a cup and a shaft of a constant velocity joint in which a cup and a shaft protruding from the cup are integrally formed without moving the constant velocity joint. In the quenching coil for the cup portion arranged inside the cup portion, a jacket for the quench portion to inject the quenching liquid to the inner surface of the cup portion, and an outer peripheral jacket to inject the quenching solution from the outside to the cup portion ,
A quenching coil for the shaft portion arranged around the shaft portion, a jacket for the shaft portion for injecting a quenching liquid to the shaft portion, and a work mounting table for rotating the mounted constant velocity joint are provided. The outer peripheral jacket is formed in a substantially U-shape, and the quenching coil for the shaft portion heats the shaft portion from the open side of the outer peripheral jacket.