JPH07305117A - Quenching apparatus for constant velocity joint - Google Patents

Abstract

PURPOSE:To shorten the time of quenching work for a constant velocity joint by simultaneously applying the quenching to a shaft part and a cup part pf the constant velocity joint. CONSTITUTION:This quenching apparatus is provided with a quenching coil 100 for cup part arranged in the inner part of the cup part WC, a jacket 150 for cup part for ejecting quenching liquid L to the cup part WC, a quenching coil 200 for shaft part arranged around the shaft part WS, a jacket 260 for shaft part for ejecting the quenching liquid L to the shaft part WS, a work loading table 300 for loading the constant velocity joint W, an electric source for supplying the current to each of quenching coils 100 and 200 and a rotatable connecting part 450 provided between the electric source and the quenching coil 200 for shaft part. The quenching coil 200 for shaft part is rotatably supported around the center axis of the shaft part WS, and the quenching coil 200 heats the shaft part WS while rotation-driven by a rotation-driving part 350.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a quenching device for a constant velocity joint for simultaneously quenching a cup portion and a shaft portion of a constant velocity joint used in a traveling system of an automobile or the like.

[0002]

2. Description of the Related Art A constant velocity joint is composed of a cup portion having a groove formed on its inner side surface and a shaft portion protruding from the cup portion. These constant velocity joints have a three-groove type with three grooves formed on the inner surface and a six-groove structure on the transfer surface.
There is a 6-groove type in which one groove is formed. The 3-groove type groove is formed deeper than the 6-groove type groove.

A quenching coil for quenching the inner surface of a cup portion of a three-groove type constant velocity joint has a pair of power feeding conductors, six vertical heating conductors for heating the inner surface, and each heating conductor. It has seven connecting conductors to be connected. At the center position of the six heating conductors, a cup jacket for injecting the quenching liquid into the cup is arranged.

A quenching coil for quenching the inner surface of a cup portion of a 6-groove type constant velocity joint comprises a pair of power supply conductors,
Both ends have a spiral heating conductor connected to these feeding conductors. At the center of the heating conductor, a cup jacket for injecting the quenching liquid into the cup is arranged.

On the other hand, the shaft portion is the same for both the 3-groove type and the 6-groove type, and a half-open saddle type quenching coil is used.

[0006]

The shaft portion is heated while the constant velocity joint is being rotated. This is the same for both the 3-groove type and the 6-groove type. On the other hand, the cup portion is heated without rotating the constant velocity joint. Therefore, the quenching of the constant velocity joint is performed in two steps: a step of quenching the shaft portion and a step of quenching the cup portion. Therefore, two hardening devices, a shaft hardening device and a cup hardening device, are required.

The present invention was devised in view of the above circumstances, and enables quenching of a shaft portion and a cup portion of a constant velocity joint at the same time so that the time for quenching the constant velocity joint can be reduced. An object of the present invention is to provide a quenching device for a constant velocity joint that can be shortened.

[0008]

A quenching device for a constant velocity joint according to the present invention is a constant velocity joint for quenching a cup portion and a shaft portion of a constant velocity joint having three grooves in a cup portion at the same time. A quenching device, which is a quenching coil for a cup arranged inside a cup, a jacket for a cup for injecting a quenching liquid into the cup, and a quenching for a shaft arranged around the shaft. A quenching coil, a jacket for the shaft that injects quenching liquid to the shaft, a work placement table on which a constant velocity joint is placed, a power supply that supplies current to each quenching coil, and this power supply and shaft And a rotatable coupling portion provided between the quenching coil and the quenching coil. The quenching coil for the shaft portion is rotatably supported around the shaft of the shaft portion, and the quenching coil for the shaft portion is provided. The coil is a rotary drive Thus while being rotated and is configured to heat the shaft portion.

A quenching device for a constant velocity joint according to the present invention is a quenching device for a constant velocity joint which simultaneously quenches a cup portion and a shaft portion of a constant velocity joint having six grooves in the cup portion. Then, the quenching coil for the cup portion arranged inside the cup portion, the jacket for the cup portion for injecting the quenching liquid into the cup portion, and the quenching coil for the shaft portion arranged around the shaft portion, A jacket for the shaft that injects quenching liquid to the shaft, a work placement table on which a constant velocity joint is placed, a power supply that supplies an electric current to each quenching coil, and a rotation drive unit that rotationally drives the work placement table. And have.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a schematic configuration diagram of a quenching device for a constant velocity joint according to a first embodiment, and FIG. 2 is a quenching device for a cup used in a quenching device for a constant velocity joint according to the first embodiment. FIG. 3 is a schematic perspective view of the quenching coil, FIG. 3 is a schematic perspective view of a quenching coil of a shaft portion and a connecting portion used in the quenching device for a constant velocity joint according to the first embodiment, and FIG. A time chart explaining the operation of the quenching device for a constant velocity joint according to an example, FIG. 5 is an explanatory view showing a cup portion of a constant velocity joint having three grooves, and FIG. 6 is a constant velocity joint according to the first embodiment. FIG. 7 is a schematic configuration diagram of another example of the connecting portion used in the quenching device of FIG. 7, and FIG. 7 is a schematic configuration diagram of another example of the connecting portion used in the quenching device of the constant velocity joint according to the first embodiment. Is.

FIG. 8 is a schematic block diagram of a quenching device for a constant velocity joint according to the second embodiment, and FIG. 9 is a cup portion used for a quenching device for a constant velocity joint according to the second embodiment. FIG. 10 is a schematic perspective view of a quenching coil, FIG. 10 is a schematic perspective view of a shaft quenching coil used in a quenching apparatus for a constant velocity joint according to a second embodiment, and FIG. 11 is a constant velocity having six grooves. It is explanatory drawing which shows the cup part of a joint. It should be noted that parts and the like that are substantially the same as the conventional ones will be given the same reference numerals for the description.

As shown in FIG. 5, the quenching device for a constant velocity joint according to the first embodiment has three grooves WC in the cup portion WC.
In a quenching device for a constant velocity joint that simultaneously quenches a cup portion WC and a shaft portion WS of a constant velocity joint W having a cup portion quenching coil 100 disposed inside the cup portion WC, Cup portion jacket 150 for injecting the quenching liquid L onto the portion WC, the shaft portion quenching coil 200 arranged around the shaft portion WS, and the shaft portion jacket for injecting the quenching liquid L onto the shaft portion WS. 260, a work placing table 300 on which the constant velocity joint W is placed, a power source (not shown) for supplying an electric current to each quenching coil 100, 200, and between this power source and the quenching coil 200 for the shaft portion. A rotatable connecting part 450 provided
And a rotation drive unit 350 that drives the shaft quenching coil 200 to rotate.

The quenching coil 100 for the cup portion is shown in FIG.
As shown in FIG. 3, a transfer surface of a three-groove type constant velocity joint is quenched, and a pair of feed conductors 110 and six heating conductors 120 connected in series between the feed conductors 110 are provided. , And seven connection conductors 130 that connect between the heating conductors 120.

The pair of power supply conductors 110 are formed by applying the quenching coil 100 for the cup portion to the current transformer 430 for the cup portion.
The secondary side coil is connected to the output terminal 440, and is formed in a substantially L shape as shown in FIGS. 1 and 2.

The two heating conductors 120 form one set, and the heating conductors 120 of each set are located on the inner surface of the cup portion WC.
It is configured to be inserted into one groove WC1 to heat each groove WC1.

Further, the heating conductors 120 are connected to each other in series by a connecting conductor 130.

Each of the conductors 110, 120 and 130 is formed of a hollow pipe, and a cooling liquid is circulated inside the conductor. Therefore, the cooling liquid is one of the power supply conductor 110, the connection conductor 130, the heating conductor 120, and the connection conductor 1.
30 → heating conductor 120 → connection conductor 130 → heating conductor 12
0 → connecting conductor 130 → heating conductor 120 → connecting conductor 130
→ heating conductor 120 → connecting conductor 130 → heating conductor 120 →
The flow flows from the connection conductor 130 to the other power supply conductor 110 in this order.

A cup portion jacket 150 for injecting the quenching liquid L onto the cup portion WC is arranged at the center position of the cup portion quenching coil 100 thus constructed, that is, at the center position of the six heating conductors 120. Has been done. The cup portion jacket 150 is configured to inject the quenching liquid L from the injection hole 151 at the tip. Since the cup portion jacket 150 is inserted into the cup portion WC so that the injection hole 151 faces the bottom portion of the cup portion WC, the quenching liquid L jetted from here is spread over the entire inner surface of the cup portion WC. It will be poured.

The shaft quenching coil 200 is a half-open saddle type quenching coil, as shown in FIG. That is, the power feeding conductor 210 having a substantially arc shape and the power feeding conductor 21
0, a pair of connecting conductors 220 connected to each other, a pair of substantially 1/4 arc-shaped first arc-shaped conductors 230 connected to the connection conductors 220, respectively, and this first arc-shaped conductor 230.
A pair of heating conductors 240 connected to each other and a second arc-shaped conductor 250 having a substantially ½ arc shape that connects the heating conductors 240.

Each of the conductors 210 and the like of the quenching coil 200 for the shaft portion is composed of a hollow pipe like the quenching coil 100 for the cup portion, and the cooling liquid is circulated therein. .

The hardening coil 200 for the shaft portion is
It is supported so as to rotate around the central axis of the shaft portion WS.

Quenching coil 200 for the shaft and power source
(Not shown), more specifically, a rotatable coupling portion 450 is provided between the current transformer 400 for the shaft portion. As shown in FIG. 3, the connecting portion 450 includes a power feeding conductor 210 forming a part of the shaft quenching coil 200 and the shaft current transformer 4.
00 secondary side coil output terminal 410. The output terminal 410 is formed in a substantially arc shape, and is provided so as to surround the power supply conductor 210 with a predetermined space. That is, the power supply conductor 210 and the output terminal 410 are not structurally connected, but are configured to be electrically connected.

The shaft quenching coil 200 having the above-described structure is rotated by the rotary drive unit 350.
It is designed to rotate about the central axis of S.
As shown in FIG. 1, the rotation driving unit 350 has a bevel gear 351 attached to the upper surface of the power feeding conductor 210 and a drive motor 352 for driving the bevel gear 351. The bevel gear 351 is made of a material having heat resistance and insulation.

The shaft portion jacket 260 is for injecting the quenching liquid L onto the shaft portion WS, and is installed on both sides of the shaft portion quenching coil 200.

The work mounting table 300 is for mounting a constant velocity joint W which is a work. The workpiece mounting table 300 has an opening 310 through which the cup quenching coil 100 and the cup jacket 150 pass. A plurality of insulating spacers 320 are provided so as to surround the opening 310. The cup portion WC of the constant velocity joint W is placed on the spacer 320.
The constant velocity joint W is placed on the work placing table 300 by placing the lower end portion of the.

The work table 300 also functions as a concentrator when heating the constant velocity joint W (that is, a function of preventing the lower end portion of the constant velocity joint W from being heated).

An outer peripheral jacket 270 for injecting the quenching liquid L on the outer peripheral surface of the cup portion WC is provided around the outer periphery of the cup portion WC. Such outer jacket 270
Is for preventing the cup portion WC from overheating.

Next, the quenching work by the quenching device for the constant velocity joint configured as described above will be described with reference to FIG. First, the constant velocity joint W is transferred onto the work mounting table 300 by a work loading device (not shown). Then, the three grooves WC1 on the inner surface of the cup portion WC
The quenching coil 100 for the cup part is inserted into the
Quenching coil 200 for the shaft part around the shaft part WS
Are placed. The cup part WC of the constant velocity joint W
The lower end portion of the is placed on the spacer 320.

In this state, the quenching coil 20 for the shaft portion
Current is supplied to the shaft part current transformer 400 from the shaft part current transformer 400 to heat the shaft part WS. Here, the shaft quenching coil 200 is rotationally driven by the rotary drive unit 350 about the central axis of the shaft WS.
Since the shaft quenching coil 200 and the shaft current transformer 400 are electrically connected by the connecting portion 450, power can be supplied to the shaft quenching coil 200.

After a predetermined time T _{1 to} T ₂ has passed since the shaft portion WS was heated, the quenching coil 10 for the cup portion 10
The current supply from the cup part current transformer 430 to 0 is started. At the same time, the quenching liquid L is sprayed from the outer peripheral jacket 270 to the outer peripheral surface of the cup portion WC.

When a predetermined time T _{2 to} T ₃ has elapsed after supplying the electric current to the quenching coil 100 for the cup portion, the power supply to both the quenching coils 100 and 200 is stopped. At the same time, the quenching liquid L is jetted from the cup jacket 150 and the shaft jacket 260, and the cup WC
And the shaft portion WS are quenched.

After a lapse of a predetermined time T _{3 to} T ₄ from the injection of the quenching liquid L, the injection of the quenching liquid L from both jackets 150, 260 and the outer jacket 270 is stopped, and the constant velocity joint W is illustrated. Not Unload the work by the work unloading device. Then, the next constant velocity joint W is carried in by the work carrying-in device, and quenching is performed in the same cycle.
The quenching liquid L from the cup part jacket 150 is
It is discharged to the outside through the opening 310.

In the quenching device for a constant velocity joint described above, the connecting portion 450 is the current transformer 40 for the shaft portion.
0 output terminal 410 and shaft quenching coil 200
However, the present invention is not limited to this.

For example, as shown in FIG. 6, a substantially cylindrical secondary coil 470 of the current transformer 400 for the shaft portion.
May be rotatably supported, and the secondary coil 470 may be rotationally driven by the rotational driving unit 350. In this case, the power feeding conductor 20 of the quenching coil 200 for the shaft portion
1, 202 are not substantially arcuate as described above,
As shown in FIG.
4 is formed so as to project along the axial direction.

The secondary coil 470 has two bearings 4
It is rotatably supported by 71, and a gear 356 is attached to the outer periphery of the upper end. This secondary coil 4
1 of the current transformer 400 for the shaft portion inside the 70
The secondary coil 460 is inserted. The primary coil 460 is not in contact with the secondary coil 470.

A drive gear 358, which is rotationally driven by a motor 357 of the rotary drive unit 350, meshes with the gear 356. Therefore, when the motor 357 is driven,
The secondary coil 470 is driven to rotate.

On the other hand, the quenching coil 200 for the shaft portion is connected to the secondary coil 470. Therefore, as the secondary coil 470 is rotationally driven, the shaft hardening coil 200 is also rotationally driven.

Further, as shown in FIG. 7, the connecting portion 450 may be constructed using a coaxial tube 480. This connecting portion 45
0, the inner conductor 481 is one output terminal 401 of the secondary coil of the current transformer 400 for the shaft portion, and the outer conductor 482 is 2 of the current transformer 400 for the shaft portion.
It has a coaxial tube 480 that is connected to the other output terminal 402 of the secondary coil and is rotatably supported.

The inner conductor 481 is installed inside the outer conductor 482, and both conductors 481 and 482 are insulated by an insulator 483. A gear 356 is provided on the outer peripheral surface of the outer conductor 482, and the gear 356 is connected to the rotation driving unit 350.
Is meshed with the drive gear 358 of the motor 357 that constitutes the.

Both ends of the inner conductor 481 protrude from the outer conductor 482, one output terminal 401 of the secondary coil is provided on one side, and the quenching coil 200 for the shaft portion is provided on the other side.
One of the power supply conductors 201 is connected to each. Since the inner conductor 481 is rotationally driven, one output terminal 401 of the secondary coil rotatably supports the inner conductor 481.

The outer conductor 482 is connected to the other output terminal 402 of the secondary coil and to the other power supply terminal 202 of the shaft quenching coil 200.

When the coaxial tube 480 is rotationally driven by the rotary driving unit 350, the shaft hardening coil 200 is rotationally driven accordingly.

Next, a quenching device for a constant velocity joint according to the second embodiment will be described with reference to FIGS. A quenching device for a constant velocity joint for simultaneously quenching a cup portion WC and a shaft portion WS of a constant velocity joint W having six grooves WC2 in the cup portion WC, the cup portion W
A quenching coil 500 for a cup portion arranged inside C,
A jacket 550 for a cup part for injecting the quenching liquid L into the cup part WC, a quenching coil 600 for the shaft part arranged around the shaft part WS, and a quenching liquid L for the shaft part WS.
Shaft jacket 660 for injecting, workpiece mounting table 700 on which constant velocity joint W is mounted, and power supply for supplying current to each quenching coil 500, 600 (not shown)
And a rotation drive unit 80 that rotationally drives the work table 700.
It has 0 and.

The quenching device for a constant velocity joint according to the second embodiment is different from the quenching device for a constant velocity joint according to the above-described first embodiment in that the cup is driven while rotating the constant velocity joint W. The point is that the portion WC and the shaft portion WS are quenched. This is because the quenching device for a constant velocity joint according to the second embodiment has six grooves W in the cup portion WC as shown in FIG.
This is because the constant velocity joint W in which C2 is formed is used as a work. Since the groove WC2 of the constant velocity joint W is shallow, even if the constant velocity joint W is rotated, it does not interfere with the quenching coil 500 for the cup portion. This is because.

As shown in FIGS. 8 and 9, the quenching coil for cup portion 500 has a pair of feeding conductors 510 and a spiral heating conductor 520 having both ends connected to the feeding conductors 510. There is. One of the power supply conductors 510 passes inside the heating conductor 520. The diameter of the heating conductor 520 is set to be slightly smaller than the inner diameter of the cup portion WC.

The quenching coil 500 for the cup portion is formed by bending a square pipe and is constructed so that the cooling liquid flows inside.

At the center of the cup quenching coil 500, that is, at the center of the heating conductor 520, a cup jacket 550 for injecting the quenching liquid L is disposed on the inner surface of the cup WC. The tip of the cup portion jacket 550 is an injection hole 551 for injecting the quenching liquid L. Since the cup portion jacket 550 is inserted into the cup portion WC so that the injection hole 551 faces the bottom portion of the cup portion WC, the quenching liquid L jetted from here is injected.
Will be poured on the entire inner surface of the cup portion WC.

On the other hand, the quenching coil 600 for the shaft portion is
As shown in FIGS. 8 and 10, it is a half-open saddle type quenching coil. That is, the pair of connecting conductors 610, the pair of substantially quarter-arc first arc-shaped conductors 620 connected to the connecting conductors 610, and the first arc-shaped conductor 6 respectively.
20 has a pair of heating conductors 630 connected to each of them, and a second arc-shaped conductor 640 having a substantially ½ arc shape that connects the heating conductors 630.

Each of the conductors 610, 620, 630, 640 of the quenching coil 600 for the shaft portion is composed of a hollow pipe, and the cooling liquid is circulated therein. Therefore, the cooling liquid is one power supply conductor 610 → one first arc conductor 620 → one heating conductor 630 → second arc conductor 640 → the other heating conductor 630 → the other first arc conductor. 620-> The other electric power feeding conductor 610 flows in order.

The shaft portion jacket 660 is for injecting the quenching liquid L onto the shaft portion WS, and is installed on both sides of the shaft portion quenching coil 600.

A peripheral jacket 270 is installed around the cup WC. The outer peripheral jacket 270 is for preventing the cup portion WC from overheating.

The work mounting table 700 mounts a constant velocity joint W which is a work. The workpiece mounting table 700 includes a rotary table 710 having an opening 711 through which the cup quenching coil 500 and the cup jacket 550 pass, and a bearing 720 provided on the lower surface side of the rotary table 710. It has a fixed base 730 for receiving the bearing 720. Therefore, the turntable 71
0 is rotatable.

A plurality of insulating spacers 712 are provided so as to surround the opening 711 of the turntable 710. By mounting the lower end portion of the cup portion WC of the constant velocity joint W on the spacer 712, the constant velocity joint W is mounted on the work mounting table 700. The work table 700 also functions as a concentrator when heating the constant velocity joint W (that is, a function of preventing the lower end portion of the constant velocity joint W from being heated).

A gear 713 is formed on the edge of the rotary table 710. The gear 713 meshes with an output gear 820 of the rotary drive unit 800 described later.

An opening 731 is formed in the fixed base 730. The opening 731 is formed in the cup quenching coil 5
00 is a portion through which the power feeding conductor 510 and the cup jacket 550 pass.

The rotation drive unit 800 includes a drive motor 810.
And a work center 830 that supports an output gear 820 that is attached to the output shaft 811 of the drive motor 810 and meshes with the gear 713, and a shaft portion WS of the constant velocity joint W that is mounted on the work mounting table 700. And have.

Therefore, when the drive motor 810 is driven, the constant velocity joint W rotates together with the work mounting table 700.

Next, the quenching work by the quenching apparatus for the constant velocity joint according to the second embodiment as described above will be explained with reference to FIG. Although FIG. 4 is a time chart explaining the operation of the quenching device for a constant velocity joint according to the first embodiment, the operation is similar to that of the quenching device for a constant velocity joint according to the second embodiment. is there.

First, the constant velocity joint W is carried onto the work placing table 700 by a work loading device (not shown). Then, the quenching coil for cup portion 500 is inserted into the inner surface of the cup portion WC, and the quenching coil for shaft portion 600 is arranged around the shaft portion WS. The lower end portion of the cup portion WC of the constant velocity joint W is placed on the spacer 712.

In this state, the quenching coil 50 for the shaft portion
Current is supplied to the shaft portion current transformer 900 from the shaft portion current transformer 900 through the output terminal 910 to heat the shaft portion WS.

After a predetermined time T _{1 to} T ₂ has passed since the shaft portion WS was heated, the quenching coil 50 for a cup portion
0 to output terminal 9 from current transformer 930 for cup
Supply of current is started via 40. At the same time, the quenching liquid L is sprayed from the outer peripheral jacket 270 to the outer peripheral surface of the cup portion WC.

When a predetermined time T _{2 to} T ₃ has passed after supplying the current to the quenching coil 500 for the cup portion, the power supply to both quenching coils 500 and 600 is stopped. At the same time, the quenching liquid L is sprayed from the cup jacket 550 and the shaft jacket 660, and the cup WC
And the shaft portion WS are quenched.

After a lapse of a predetermined time T _{3 to} T ₄ from the injection of the quenching liquid L, the injection of the quenching liquid L from both jackets 550, 660 and the outer peripheral jacket 270 is stopped, and the constant velocity joint W is illustrated. Not Unload the work by the work unloading device. Then, the next constant velocity joint W is carried in by the work carrying-in device, and quenching is performed in the same cycle.
The quenching liquid L from the cup jacket 550 is
It is discharged to the outside through the openings 711 and 731.

In the above-mentioned two embodiments, the current transformer for the cup portion and the current transformer for the shaft portion are described as separate components, but the present invention is not limited to this. A single current transformer may supply current to the quenching coil for the cup portion and the quenching coil for the shaft portion.

[0065]

The quenching device for a constant velocity joint according to the present invention is a quenching device for a constant velocity joint that simultaneously quenches the cup portion and the shaft portion of a constant velocity joint having three grooves in the cup portion. Then, the quenching coil for the cup portion arranged inside the cup portion, the jacket for the cup portion for injecting the quenching liquid into the cup portion, and the quenching coil for the shaft portion arranged around the shaft portion, A jacket for the shaft part that injects the quenching liquid to the shaft part, a work mounting table on which a constant velocity joint is mounted, a power supply that supplies an electric current to each quenching coil, this power supply and the quenching coil for the shaft part And a rotatable coupling portion provided between the shaft portion and the shaft quenching coil. The shaft quenching coil is rotatably supported around the shaft of the shaft portion, and the shaft quenching coil is rotationally driven. Rotation by part While it is configured to heat the shaft portion. Therefore, it is possible to quench the inner surface side of the cup portion and the shaft portion of the constant velocity joint at the same time, so that it is possible to shorten the quenching time of the constant velocity joint.

Further, the connecting portion is defined by claim 2, 3 or 4.
By configuring as described above, the quenching coil for the shaft portion can be rotated, and the constant velocity joint, especially 3
It is possible to quench the inner surface side of the cup portion having two grooves and the shaft portion at the same time.

A quenching device for a constant velocity joint for simultaneously quenching a cup portion and a shaft portion of a constant velocity joint having six grooves in the cup portion, wherein the cup portion is disposed inside the cup portion. Quenching coil, a jacket for the cup that injects the quenching liquid into the cup, a quenching coil for the shaft that is arranged around the shaft, and a jacket for the shaft that injects the quenching liquid onto the shaft. And a work mounting table on which the constant velocity joint is mounted, a power source for supplying an electric current to each quenching coil, and a rotation drive unit for rotationally driving the work mounting table. Therefore, the inner surface of the cup portion and the shaft portion can be simultaneously quenched while the constant velocity joint is rotationally driven, so that the time required for quenching the constant velocity joint can be shortened.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of a quenching device for a constant velocity joint according to a first embodiment.

FIG. 2 is a schematic perspective view of a cup quenching coil used in the quenching device for a constant velocity joint according to the first embodiment.

FIG. 3 is a schematic perspective view of a shaft quenching coil and a connecting portion used in the quenching device for a constant velocity joint according to the first embodiment.

FIG. 4 is a time chart for explaining the operation of the quenching device for a constant velocity joint according to the first embodiment.

FIG. 5 is an explanatory view showing a cup portion of a constant velocity joint having three grooves.

FIG. 6 is a schematic configuration diagram of another example of a connecting portion used in the quenching device for a constant velocity joint according to the first embodiment.

FIG. 7 is a schematic configuration diagram of another example of a connecting portion used in the quenching device for a constant velocity joint according to the first embodiment.

FIG. 8 is a schematic configuration diagram of a quenching device for a constant velocity joint according to a second embodiment.

FIG. 9 is a schematic perspective view of a cup quenching coil used in a quenching device for a constant velocity joint according to a second example.

FIG. 10 is a schematic perspective view of a shaft quenching coil used in a quenching device for a constant velocity joint according to a second embodiment.

FIG. 11 is an explanatory diagram showing a cup portion of a constant velocity joint having six grooves.

[Explanation of symbols]

 100 Quenching coil for cup part 150 Jacket for cup part 200 Quenching coil for shaft part 260 Jacket for shaft part 300 Work rest table 350 Rotation drive part 450 Connection part 500 Quenching coil for cup part 550 Cup part jacket 600 Shaft part Quenching coil 660 Shaft quenching coil 700 Work rest table 800 Rotation drive unit W Constant velocity joint WC Cup portion WC1 and WC2 groove WS Shaft portion L Quenching liquid

Claims (5)

[Claims] 1. A quenching device for a constant velocity joint, wherein a cup portion and a shaft portion of a constant velocity joint having three grooves in the cup portion are simultaneously quenched, and a quenching device for a cup portion disposed inside the cup portion. A quenching coil, a jacket for a cup that injects a quenching liquid into the cup, a quenching coil for a shaft that is arranged around the shaft, and a jacket for a shaft that injects a quenching liquid onto the shaft, The work mounting table on which the constant velocity joint is mounted, a power supply for supplying an electric current to each quenching coil, and a rotatable connecting portion provided between the power supply and the quenching coil for the shaft portion are provided. And
The quenching coil for the shaft portion is rotatably supported around the shaft of the shaft portion, and the quenching coil for the shaft portion heats the shaft portion while being rotationally driven by a rotary drive unit. Quenching equipment for quick joints. 2. The connecting portion comprises an output terminal formed in a substantially arc shape of a secondary coil of a current transformer for a shaft portion, and a feed conductor formed in a substantially arc shape of a quenching coil for a shaft portion. 2. The quenching device for a constant velocity joint according to claim 1, wherein the quenching device is configured such that the output terminal surrounds the power feeding conductor without directly contacting the power feeding conductor. 3. The connecting portion has a secondary coil of a current transformer for a shaft portion rotatably supported, and the rotation driving portion rotates the secondary coil to rotate the shaft portion. The quenching device for a constant velocity joint according to claim 1, wherein the quenching coil for use is driven to rotate. 4. An inner conductor of the connecting portion is connected to one output terminal of a secondary coil of a current transformer for a shaft portion,
The outer conductor has a coaxial tube connected to the other output terminal of the secondary coil of the current transformer for the shaft portion and rotatably supported, and the quenching coil for the shaft portion has the coaxial tube. 2. The constant velocity according to claim 1, further comprising a current transformer for a shaft portion, wherein the rotation drive portion rotationally drives the coaxial tube to rotationally drive the quenching coil for the shaft portion. Quenching equipment for joints. 5. A quenching device for a constant velocity joint which simultaneously quenches a cup portion and a shaft portion of a constant velocity joint having six grooves in the cup portion, and a quenching device for the cup portion arranged inside the cup portion. A quenching coil, a jacket for a cup that injects a quenching liquid into the cup, a quenching coil for a shaft that is arranged around the shaft, and a jacket for a shaft that injects a quenching liquid onto the shaft, Quenching of a constant velocity joint, comprising: a work placing table on which a constant velocity joint is placed; a power supply that supplies an electric current to each quenching coil; and a rotation drive unit that rotationally drives the work placing table. apparatus.