KR20240060332A - Inner-race manufacturing apparatus of Constant velocity joint - Google Patents

Abstract

The present invention relates to an inner race processing device for a constant velocity joint. More specifically, when machining a ball track of an inner race, roughing, finishing, and chamfering can be processed using one device. Furthermore, the equipment can be miniaturized. This relates to an inner race processing device for constant velocity joints that can significantly reduce costs and significantly improve productivity.
The present invention includes an inner race track processing device (200); It includes an inner race operating device 300 for supplying an inner race 400 to the inner race track processing device 200, wherein the inner race track processing device 200 includes a frame portion 102; Housing parts 104 and 105 installed on the left and right sides of the frame part 102 so as to be rotatable at a predetermined angle; a rotation drive unit 106 connected to and installed on one side of the housing unit 104; a rotation drive unit 108 connected to one side of the housing unit 105 to rotate the housing unit 105; A roughing processing device 110 installed vertically on the upper part of the frame portion 102; A finishing processing device 112 installed vertically on the right side of the rough processing device 110; A chamfering device 114 is located between the roughing processing device 110 and the finishing processing device 112 and is installed in a triangular shape to perform roughing and finishing processing when machining the ball track of the inner race 400. It is desirable to be able to perform the processing and chamfering in one device.
As such, the inner race processing device for the constant velocity joint of the present invention allows processing using a single device, so there is no need to move the inner race, which has the effect of dramatically shortening the process, thereby speeding up the working time and greatly increasing productivity. There is an improving effect.
In addition, the present invention has the effect of significantly reducing the installation cost of the equipment and significantly improving the processing precision of the inner race by performing roughing, finishing, and chamfering within one device.

Description

Inner-race manufacturing apparatus of Constant velocity joint}

The present invention relates to an inner race processing device for a constant velocity joint. More specifically, when machining a ball track of an inner race, roughing, finishing, and chamfering can be processed using one device. Furthermore, the equipment can be miniaturized. This relates to an inner race processing device for constant velocity joints that can significantly reduce costs and significantly improve productivity.

In general, a constant velocity joint consists of an outer race, an inner race, a ball that transmits torque, and a cage that contains the ball.

The torque of the constant velocity joint is transmitted via a plurality of balls pressed between the inner race and the outer race.

A plurality of balls are located on each bisecting plane created by intersecting the center lines of the inner race and the outer race.

The inner race used in the constant velocity joint is one of the key components of the constant velocity joint. In particular, the inner race has an important function that allows the ball to roll smoothly while contacting the outer race inside the ball cage.

The inner race shape of the constant velocity joint has 6-8 ball tracks on the outside and is formed in a spline structure where the shaft is connected on the inside. The core functions of the ball track are ball acceptance, smooth ball rolling, and splines that operate without backlash.

For the ball track of this inner race, the shape dimension precision and surface roughness of the ball track are important factors in order for the combined balls to roll smoothly, and among them, surface roughness (Ra) is the most important factor.

Therefore, in order to precisely process the ball track of the inner race, after the cutting process is completed, the ball track is precisely processed through additional grinding process.

A device for polishing a workpiece is disclosed in Patent Publication No. 10-2013-0029174.

The conventional polishing device relates to an angle-adjustable type tracing roll, which consists of a guider at the bottom and a left and right support having a first guide groove formed in the front and rear direction at the top, and is coupled to the first guide groove of the left and right support through a bolt and nut combination. It is installed on the upper part of a front and rear stand forming an arc-shaped second guide groove and an angle adjustment scale, and is coupled and installed to the second guide groove of the front and rear stand through a bolt and nut combination, and a housing composed of a fitting groove and a fixed installation part, A spindle consisting of a housing and a seating slide groove that is coupled to the inner diameter of the housing and installed on one side of the housing, and a reciprocating screw coupled to the spindle on one side and a handle on the other side are provided to transfer the spindle to the left and right. A polishing means consisting of left and right transport means, a fixing pad, a rotation prevention means, a bearing housing, a shaft, and a polishing wheel, and an operating motor installed on the upper side of the spindle through a bracket and coupled with a belt pulley to rotate the polishing means. It consists of

The polishing device configured in this way is transported to the left and right based on the workpiece to be polished and polishes the portion to be polished on the workpiece.

However, conventional polishing equipment is capable of polishing straight groove shapes or concave groove shapes, but it is not possible to polish shapes where convex and concave parts coexist, such as the ball track of the inner race.

In particular, in the case of burrs remaining in the web area of the ball track after roughing and finishing processing of the ball track, it had to be processed using a separate device, which required work processes, work time, and manpower. Since a device was required, there were problems with limitations such as device cost and installation space.

In order to solve this problem, the present applicant has made excellent improvements to enable roughing, finishing and chamfering of ball tracks within a single device.

Korean Patent Publication No. 10-2013-0029174 Korean Patent No. 10-2210847

The present invention was developed to solve the above problems, and provides an inner race processing device for a constant velocity joint developed to enable roughing, finishing, and chamfering of the ball track of the inner race using a single device. It is for that purpose.

The purpose of the present invention is to provide an inner race processing device for a constant velocity joint developed to quickly and precisely perform chamfering accompanying ball track processing of the inner race.

The purpose of the present invention and its technical problems are not limited to the technical problems described above. Therefore, other technical problems that are not mentioned will be clearly understood by those skilled in the art from the description below.

The present invention includes an inner race track processing device (200); It includes an inner race operating device 300 for supplying an inner race 400 to the inner race track processing device 200, wherein the inner race track processing device 200 includes,

Frame portion 102; Housing parts 104 and 105 installed on the left and right sides of the frame part 102 so as to be rotatable at a predetermined angle; a rotation drive unit 106 connected to and installed on one side of the housing unit 104; a rotation drive unit 108 connected to one side of the housing unit 105 to rotate the housing unit 105; A roughing processing device 110 installed vertically on the upper part of the frame portion 102; A finishing processing device 112 installed vertically on the right side of the rough processing device 110; A chamfering device 114 is located between the roughing processing device 110 and the finishing processing device 112 and is installed in a triangular shape to perform roughing and finishing processing when machining the ball track of the inner race 400. It is characterized by the ability to perform chamfering and chamfering in one device.

The roughing processing device 110 and the finishing processing device 112 of the present invention,

a spindle unit 116; a processing tool housing unit 118 installed on the spindle unit 116; A processing tool unit 120 installed on the upper part of the processing tool housing unit 118; A motor unit 128 is provided on the inside of the roughing processing device 110 and the finishing processing device 112, which are installed on the inside to rotate the spindle unit 116, and is installed on the processing tool unit 120 and the spindle unit. It is preferable to include a roughing tool tip portion 122 and a finishing tool tip portion 124 that perform roughing and finishing processing while rotating by the portion 116.

The chamfering device 114 is,

Deburring spindle part 130;

A processing tool unit 132 installed on the deburring spindle unit 130;

A chamfering tool tip portion 134 installed on the upper part of the processing tool portion 132;

It is preferable to include a motor unit 128 installed inside the chamfering device to rotate the deburring spindle unit 130.

As such, the inner race processing device for the constant velocity joint of the present invention allows processing using a single device, so there is no need to move the inner race, which has the effect of dramatically shortening the process, thereby speeding up the working time and greatly increasing productivity. There is an improving effect.

In addition, the present invention has the effect of significantly reducing the installation cost of the equipment and significantly improving the processing precision of the inner race by performing roughing, finishing, and chamfering within one device.

1 is a front view showing the structure of the inner race processing device of the constant velocity joint of the present invention.
Figure 2 is an exploded view showing the structure of the inner race processing device of the constant velocity joint of the present invention.
Figure 3 is a view showing the structure of the finishing processing device of the inner race processing device of the constant velocity joint of the present invention.
Figure 4 is a view showing the structure of the spindle portion of the inner race processing device of the constant velocity joint of the present invention.
Figure 5 is an exploded view of Figure 4
Figure 6 is a view showing the structure of the deburring spindle part of the inner race processing device of the constant velocity joint of the present invention.
Figure 7 is an exploded view of Figure 6
Figure 8 is a plan view showing the structure of the inner race processing device of the constant velocity joint of the present invention.
Figure 9 is a view showing the processing angle of the inner race ball track of the present invention

The following objects, other objects, features and advantages of the present invention will be easily understood through the following preferred embodiments in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms.

Rather, the embodiments introduced herein are provided so that the disclosure will be thorough and complete and so that the spirit of the invention can be sufficiently conveyed to those skilled in the art.

Embodiments described and illustrated herein also include complementary embodiments thereof.

As used herein, singular forms also include plural forms, unless specifically stated otherwise in the context. As used in the specification, elements referred to as 'comprise' and/or 'comprising' do not exclude the presence or addition of one or more other elements.

The present invention includes an inner race track processing device (200); It includes an inner race operating device 300 for supplying an inner race 400 to the inner race track processing device 200, wherein the inner race track processing device 200 includes a frame portion 102; Housing parts 104 and 105 installed on the left and right sides of the frame part 102 so as to be rotatable at a predetermined angle; a rotation drive unit 106 connected to and installed on one side of the housing unit 104; a rotation drive unit 108 connected to one side of the housing unit 105 to rotate the housing unit 105; A roughing processing device 110 installed vertically on the upper part of the frame portion 102; A finishing processing device 112 installed vertically on the right side of the rough processing device 110; A chamfering device 114 is located between the roughing processing device 110 and the finishing processing device 112 and is installed in a triangular shape to perform roughing and finishing processing when machining the ball track of the inner race 400. It is desirable to be able to perform the processing and chamfering in one device.

The roughing processing device 110 and the finishing processing device 112 of the present invention include a spindle unit 116; a processing tool housing unit 118 installed on the spindle unit 116; A processing tool unit 120 installed on the upper part of the processing tool housing unit 118; A motor unit 128 is provided on the inside of the roughing processing device 110 and the finishing processing device 112, which are installed on the inside to rotate the spindle unit 116, and is installed on the processing tool unit 120 and the spindle unit. It includes a roughing tool tip portion 122 and a finishing tool tip portion 124 that perform rough machining and finishing machining while rotating by the portion 116.

The chamfering device 114 includes a deburring spindle unit 130; A processing tool unit 132 installed on the deburring spindle unit 130; A chamfering tool tip portion 134 installed on the upper part of the processing tool portion 132; It includes a motor unit 128 installed inside the chamfering device to rotate the deburring spindle unit 130.

Hereinafter, specific embodiments of the inner race processing apparatus for the constant velocity joint for a gutter of the present invention will be described.

Figure 1 is a front view showing the structure of the inner lace processing device of the constant velocity joint of the present invention, Figure 2 is an exploded view showing the structure of the inner lace processing device of the constant velocity joint of the present invention, and Figure 3 is the inner lace processing device of the constant velocity joint of the present invention. This is a drawing showing the structure of the finishing processing device of the lace processing device.

And, Figure 4 is a diagram showing the structure of the spindle portion of the inner lace processing device of the constant velocity joint of the present invention, Figure 5 is an exploded view of Figure 4, and Figure 6 is a deburring spindle portion of the inner lace processing device of the constant velocity joint of the present invention. This is a diagram showing the structure, and Figure 7 is an exploded view of Figure 6.

In addition, Figure 8 is a plan view showing the structure of the inner race processing device of the constant velocity joint of the present invention, and Figure 9 is a diagram showing the processing angle of the inner race ball track of the present invention.

When explaining the inner race processing device of the constant velocity joint of the present invention with reference to FIGS. 1 to 9, first, as shown in FIG. 1, the inner race processing device 100 of the constant velocity joint of the present invention has an inner race track. It includes a processing device 200 and an inner race operation device 300 that inputs the inner race 400 into the inner race track processing device 200.

And the inner race track processing device 200 includes a frame portion 102, a housing portion 104 and 105, a rotation drive portion 106 and 108, a roughing processing device 110, a finishing processing device 112, and a chamfering device 114. ) includes.

Additionally, the inner race operating device 300 includes a housing 302, a shaft 304, a drawbar 306, a chuck 308, and a collet 310.

The inner race track processing device 200 is a device for processing the ball track 402 of the inner race 400. It roughens the ball track 402 of the inner race 400 and performs finishing processing again after rough machining. After performing the roughing and finishing machining, burrs remaining around or on the edges of the ball track 402 are removed and chamfering is performed to precisely machine the inner race.

The inner race track processing device 200 is installed, and an inner race operating device 300 is installed on the upper part of the inner race track processing device 200 to grab the inner race 400 and move it up and down while supplying it.

The inner race track processing device 200 includes a roughing processing device 110 for processing the ball track 402 of the inner race 400, a finishing processing device 112 for finishing the ball track 402, and , After performing the rough machining and finishing machining, a chamfering device 114 is provided for precisely machining the surface or edge of the ball track 402.

And, to the upper part of the inner race track processing device 200, the inner race 400 is supplied downward from the top, rough processing is performed through the rough processing device 110, and then moved again to finish processing through the finishing processing device 112. An inner race operating device 300 is installed to process and move it back to the chamfering device 114 for chamfering processing.

The inner race track processing device 200 is first equipped with a frame portion 102, a housing portion 104 is fixedly installed at the upper left portion of the frame portion 102, and a housing portion 104 is fixedly installed at the upper right portion of the frame portion 102. The housing portion 105 is fixedly installed.

Additionally, a rotation drive unit 106 is connected to and installed on the left side of the housing unit 104, and a rotation drive unit 108 is installed on the right side of the housing unit 105.

The rotation drive unit 106 is connected to the housing unit 104 so that the housing unit 104 can rotate forward and backward, and the rotation drive unit allows the housing unit 105 to also rotate forward and backward. It is installed in connection with (108).

The housing parts 104 and 105 rotate in the front and rear directions and the angle is adjusted by the rotation driving parts 106 and 108, and the frame part 102 is connected and fixed so that the housing parts 104 and 105 rotate together.

In addition, a roughing processing device 110 is installed on the upper left side of the frame portion 102, and a finishing processing device 112 is installed on the upper right side of the frame portion 102, and the roughing processing device 110 and the finishing processing device 110 A chamfering device 114 is installed in the front middle portion of the processing device 112.

The roughing processing device 110, the finishing processing device 112, and the chamfering device 114 are positioned to form an equilateral triangle, and the inner race operating device 300 moves clockwise and moves upwards of the roughing processing device 110. It is located at and moves downward to supply the inner race (400).

In addition, it is located above the finishing device 112 and moves downward to supply the inner race 400, and it is located above the chamfering device 114 and supplies the inner race 400 while moving downward. Processing takes place.

When explaining with reference to Figures 2 and 3, first, a frame part 102 is installed in the horizontal direction, and a housing part 104 is installed protruding upward from the left side of the frame part 102, A housing portion 105 is installed to protrude upward from the right side of the frame portion 102.

A rotation drive unit 106 is connected to the left side of the housing unit 104, and a rotation drive unit 108 is connected to the right side of the housing unit 105. The rotation drive unit 108 is connected to the outside. Power is transmitted from a power source to rotate the housing unit 105, and the frame unit 102 connected to the housing unit 105 is rotated at a predetermined angle in the forward and backward directions.

The housing portions 104 and 105 are rotated and the predetermined angle for processing the ball track 402 is preferably in the range of 5 degrees to 30 degrees.

The roughing processing device 110, the finishing processing device 112, and the chamfering device 114 are installed in the frame portion 102, and the frame portion 102 rotates together.

An inner race operating device 300 is installed on the upper part of the inner race track processing device 200 to supply the inner race 400. The inner race operating device 300 includes a housing 302 and a shaft. It includes (304), a drawbar (306), a chuck (308), and a collet (310).

The housing 302 is formed in a cylindrical shape, and a shaft 304 is installed on the inner part of the housing 302. A draw bar 306 is installed at the lower end of the shaft 304, and the draw bar 306 At the end of the collet 310 is connected to the lower part.

The drawbar 306 and collet 31 are installed inside the chuck 308.

The draw bar 306 and the collet 310 are connected and fixed by a fixing means such as a collet fixing bolt (not shown), and are precisely fixed using the collet fixing bolt. That is, the lower end of the draw ratio 306 is connected to the collet 310, and a precise run out can be set according to the fastening and releasing of the collet fixing bolt, and is set in the 2-3㎛ range.

Meanwhile, the roughing processing device 110 includes a spindle unit 116, a processing tool housing unit 118 installed on the upper part of the spindle unit 116, and a machining tool housing unit 118 installed on the upper part of the processing tool housing unit 118. It is provided with a tool unit 120, a roughing tool tip unit 122 installed on the upper part of the processing tool unit 120, and a motor unit 126 for rotating the processing tool unit 120.

And the finishing device 112 includes a spindle unit 116, a processing tool housing unit 118 installed on the upper part of the spindle unit 116, and a processing tool unit installed on the upper part of the processing tool housing unit 118. It is provided with (120), a finishing tool tip part 124 installed on the upper part of the processing tool unit 120, and a motor unit 128 for rotating the processing tool unit 120.

At this time, the chamfering device 114 includes a deburring spindle part 130, a processing tool part 132 installed on the upper part of the deburring spindle part, and a chamfering tool tip part 134 installed on the upper part of the processing tool part 132. Equipped with

As shown in Figure 3, the finishing processing device 112 is installed on the frame portion 102, and a chamfering device 114 is installed on the left side thereof.

At this time, the finishing processing device 112 is equipped with a spindle unit 116, and a motor unit 128 that rotates the spindle unit 116 is installed therein.

A chamfering device 114 including a deburring spindle unit 130 is provided on the left side of the finishing processing device 112, and after the ball track is processed by the finishing processing device 112, the chamfering device 114 is used. The outer surface of the inner race 400 is processed precisely and smoothly.

Subsequently, Figures 4 and 5 are diagrams showing the structure of the spindle portion of the roughing processing device and the finishing processing device of the present invention, in which a cylindrical housing body 10 is formed, and the inner right portion of the housing body 10 A motor unit coupling groove 12 is formed, and a bearing coupling groove 14 is formed on the inner left side of the housing body 10.

A cover coupling protrusion 16 protruding in the inner diameter direction is formed at the left end of the bearing coupling groove 14, a kerbal coupling groove 18 is formed in the cover coupling protrusion 16, and the motor unit coupling groove 12 is formed at the left end of the bearing coupling groove 14. A cylindrical coil housing 20 is inserted and installed.

In addition, a housing cover 22 is installed on the right side of the housing body 10, a shaft fixing body 24 is formed in the center of the housing cover 22, and a shaft fixing body 24 is formed in the center of the shaft fixing body 24 to the left and right. The shaft hole 26 is formed to do so.

Meanwhile, motor units 126 and 128 having a coil 28 are inserted and installed on the inner side of the coil housing 20.

As described above, the housing cover 22 is installed on the right side of the housing body 10, and the spindle cover body 30 is coupled and installed on the right side of the housing cover 22.

A shaft 32 is inserted and installed in the axial hole 26 in the horizontal direction, and a first bearing 34 and a second bearing 36 are inserted and installed in the bearing coupling groove 14, and the first bearing 34 and It is preferable that a spacer 35 is installed between the second bearings 36.

Next, a housing cover 38 is installed on the left side of the housing body 10, and a cylindrical shaft fixing body 40 is formed on the right side of the housing cover 38, and the shaft fixing body 40 ), an axial hole 42 penetrating in the horizontal direction is formed in the central portion, and a housing wing cover body 44 is formed on the outer peripheral surface of the housing cover 38.

The outer peripheral surface of the housing wing cover body 44 is formed in a sawtooth shape, making it easy to insert and difficult to remove when combined with the processing tool unit 120. At this time, the angle of the sawtooth shape is in the range of 2-10 degrees. desirable. This is because if it is less than 2 degrees, it can be easily attached and detached, which reduces the solid fixation, and if it is more than 10 degrees, it is difficult to join and the working time is reduced.

It is preferable that the first bearing 34 coupled to the bearing coupling groove 14 uses a needle bearing and the second bearing 36 uses a ball bearing.

Inside the middle portion of the housing body 10, a plurality of outlet holes 11 through which coolant passes are formed.

Next, Figures 6 and 7 are diagrams showing the structure of the deburring spindle part of the chamfering device of the present invention, in which a cylindrical housing body 46 is formed, and a motor unit coupling groove is formed on the inner right side of the housing body 46. (48) is formed, a bearing coupling groove 50 is formed on the inner left side of the housing body 46, and a housing cover 52 is coupled and installed on the left side of the housing body 46.

A shaft 54 is horizontally coupled and installed on the inner side of the housing body 46. A first bearing 56 is installed on the left end of the shaft 54, and a first bearing 56 is installed on the right end of the shaft 54. A second bearing 58 is fitted and installed.

In addition, a housing cover body 60 is installed on the right side of the housing body 46, and a bearing coupling groove 62 is formed on the inner side of the housing cover body 60, and the bearing coupling groove 62 has the above-mentioned The second bearing 58 is coupled and rotation occurs.

The motor unit 128 is installed in the motor unit coupling groove 48 formed in the middle of the housing body 46 formed as described above, and the middle part of the shaft 54 is coupled to the inner part of the motor unit 128. It is installed and rotates.

Meanwhile, as it is coupled and installed on the right side of the housing body 46, the second bearing 58 coupled to the shaft 54 described above is inserted into the bearing coupling groove 62 of the housing cover body 60. This ensures smooth rotation.

Next, the housing outer body 64 and the housing inner body 66 are coupled and installed on the right side of the housing cover body 60.

An outer body coupling groove 65 is formed on the outer peripheral surface of the housing outer body 64, and an inner coupling jaw 67 is formed protruding on the outer peripheral surface of the housing inner body 66.

And the housing cover body 64 is formed by fitting and fixing the inner coupling jaw 67 in the outer body coupling groove 65, and a shaft coupling groove 68 penetrating left and right in the center of the housing cover body 64. This is formed.

It is preferable that the right end of the shaft 54 described above is installed in the shaft coupling groove 68 so that it is fitted and fixed.

A coupling flange 70 is formed on the outer side of the housing cover body 64 by protruding in the outer circumferential direction.

In addition, a spindle cover body 72 is installed on the right side of the housing cover body 60, and a flange coupling groove 74 is formed on the inner peripheral surface of the spindle cover body 72, and the spindle cover body 72 ), an axial hole 76 penetrating in the left and right directions is formed in the central portion.

The coupling flange 70 protruding from the outer side of the housing cover body 64 is press-fitted and fixed to the flange coupling groove 74.

Figure 8 is a plan view showing the structures of the roughing processing device, the finishing processing device, and the chamfering device of the present invention.

First, the frame portion 102 is installed, the housing portion 104 is installed on the left side of the frame portion 102, the housing portion 105 is installed on the right side, and the left central portion of the frame portion 102 is roughed. The processing device 110 is located, and the finishing processing device 112 is located on the right side of the rough processing device 110, and the chamfering device 114 is located in the middle of the rough processing device 110 and the finishing processing device 112. is installed.

And, Figure 9 is a diagram showing the processing angle of the inner race ball track of the present invention, and the inner race processing device of the present invention installed as described above changes the inclined angle 404 of the ball track 402 to a vertical 10- Rough cutting and finishing are performed at an angle in the 15 degree range. More preferably, the angle 404 of the ball track is processed to be inclined at 11 degrees.

The technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be variously performed by those skilled in the art from the description below. And technical changes within this scope will be said to be within the scope of the present invention.

10: Housing body 12: Motor unit coupling groove
14: Bearing coupling groove 16: Cover coupling jaw
18: Cover coupling groove 20: Coil housing
22: Housing cover 24: Axis fixing body
26: shaft hole 28: coil
30: Spindle body cover 32: Shaft
34: first bearing 36: second bearing
38: Housing cover 40: Axis fixing body
42: shaft hole 44: housing wing cover body
46: Housing body 48: Motor unit coupling groove
50: Bearing coupling groove 52: Housing cover
54: shaft 56: first bearing
58: second bearing 60: housing cover body
62: Bearing coupling groove 64: Housing outer cover body
66: Housing inner cover body 68: Shaft coupling groove
70: Clamping flange 72: Spindle cover body
74: Flange coupling groove 76: Axial hole
100: Inner lace processing device 102: Frame portion
104,105: housing part 106: rotation driving part
108: rotation driving unit 110: roughing processing device
112: Finishing processing device 114: Chamfering device
200: Inner race track processing device 300: Inner race operating device
400: Inner Race 402: Ball Track
404: Angle of ball track

Claims (3)

an inner race track processing device (200);
It includes an inner race operating device 300 for supplying the inner race 400 to the inner race track processing device 200,
The inner race track processing device 200,
Frame portion 102;
Housing parts 104 and 105 installed on the left and right sides of the frame part 102 so as to be rotatable at a predetermined angle;
a rotation drive unit 106 connected to and installed on one side of the housing unit 104;
a rotation drive unit 108 connected to one side of the housing unit 105 to rotate the housing unit 105;
A roughing processing device 110 installed vertically on the upper part of the frame portion 102;
A finishing processing device 112 installed vertically on the right side of the rough processing device 110;
A chamfering device 114 is located between the roughing processing device 110 and the finishing processing device 112 and is installed in a triangular shape to perform roughing and finishing processing when machining the ball track of the inner race 400. An inner race processing device for a constant velocity joint, characterized in that chamfering and chamfering can be performed in one device.
According to clause 1,
The roughing processing device 110 and the finishing processing device 112,
a spindle unit 116;
a processing tool housing unit 118 installed on the spindle unit 116;
A processing tool unit 120 installed on the upper part of the processing tool housing unit 118;
A motor unit 128 is provided on the inner side of the roughing processing device 110 and the finishing processing device 112 installed on the inner side to rotate the spindle portion 116,
A constant velocity joint comprising a roughing tool tip portion 122 and a finishing tool tip portion 124 installed on the processing tool portion 120 and rotating by the spindle portion 116 to perform roughing and finishing processing. Inner lace processing device.
According to clause 1,
The chamfering device 114 is,
Deburring spindle part 130;
A processing tool unit 132 installed on the upper part of the deburring spindle unit 130;
A chamfering tool tip portion 134 installed on the upper part of the processing tool portion 132;
An inner race processing device for a constant velocity joint, characterized in that it includes a motor unit 128 installed inside the chamfering device to rotate the deburring spindle unit 130.