KR102017521B1 - Inner ball joint assembly measuring device - Google Patents

Abstract

The present invention relates to a device for measuring an inner side for an inner ball joint assembly. A pair of rotation operating units are coupled by a rotary shaft. A measurement unit tightly attached to an inner surface of a fixing end fixing a ball member when front ends of the rotation operating units are rotated to both sides based on the rotary shaft is formed on front surfaces of the rotation operating units to be bent. A variable resistor sensing a rotated angle of the measurement unit to generate an identifiable electric signal is formed on lower portions of the rotation operating units to be connected to a lower end of the rotary shaft. A display unit with a control unit for converting an electric signal inputted from the variable resistor into a length unit to output a measurement value is formed on one surface of the rotation operating units. A measurement task of measuring the inner diameter of the fixing end fixing the ball member can be performed by a single task. Inner diameter length measurement of fixing ends arranged on inner ball joint assemblies manufactured in various sizes can be easily performed.

Description

Inner ball joint assembly measuring device for caulking part of ball housing for inner ball joint assembly

The present invention relates to a caulking unit inner diameter measuring device of the ball housing for the inner ball joint assembly, and more specifically, coupled to the rotating shaft consisting of a pair of the rotating shaft, the front surface of the rotating actuator is rotated to both sides about the rotating shaft When the front end of the part is rotated to form a measuring part in close contact with the inner surface of the fixed end for holding the ball member is bent on the front surface of the rotary operation unit, the variable resistance for generating a identifiable electrical signal by sensing the rotated angle of the measuring unit The ball member may be formed on one surface of the rotary actuator by a display unit formed at a lower portion of the rotary actuator so as to be connected to the lower end of the rotary shaft, and having a control unit for converting an electric signal input from a variable resistor into units of length to output a measured value. The measuring operation to measure the inner diameter of the fixed end to be fixed in one operation In addition, it is possible to easily measure the inner diameter length of the fixed end provided in the inner ball joint assembly manufactured in various sizes, the measurement unit is set to zero display unit in the state coupled to the zero adjustment jig equipped with a plurality of jig grooves After that, the measurement unit is in close contact with the inner surface of the fixed end to determine whether the measured value output through the display unit is within a predetermined error range, thereby significantly reducing the measurement time of the inner ball joint, thereby outputting through the display unit. The present invention relates to an internal diameter measuring device for caulking portion of a ball housing for an inner ball joint assembly, which improves the reliability of an inner diameter length measurement value of a fixed end to improve productivity of an inner ball joint assembly.

In general, a vehicle steering device is provided between the steering wheels so as to transmit the rotational force generated from the steering wheels to the steering wheels, the steering shafts connected to the steering wheels, the rack housings connected to the steering wheels, and the wheel shafts on both sides of the rack housings. It is provided with an inner ball joint connected to allow the user to drive the vehicle in the desired direction.

10 illustrates a conventional inner ball joint assembly.

The inner ball joint assembly is roughly divided into a tie rod 200 and a ball housing 210 as shown in FIG.

The tie rod 200 is formed in a pipe shape, and a ball member 201 is formed below the tie rod 200.

The ball housing 210 is provided with a coupling groove 211 into which the ball member 201 is fitted, and a threaded portion 220 connected to a rack bar (not shown) is formed at a lower end of the ball housing 210.

When explaining the coupling state of the inner ball joint assembly configured as described above,

First, pressure pressing and caulking the upper portion of the ball housing 210 in a state in which the ball member 201 is fitted into the coupling groove 211 of the ball housing 210.

Since the upper portion of the ball housing 210 by pressing pressing caulk, the upper end of the ball housing 210 is formed with a fixed end 212 bent in the coupling groove 211 inside the ball member (210) inserted into the coupling groove (211) 201 may be coupled to the ball housing 210.

As such, the inner diameter of the caulking portion (the inner diameter of the fixed end) after the caulking operation is completed in the inner ball joint that couples the ball member 201 to the ball housing 210 by the caulking operation, which greatly affects the operation performance of the inner ball joint. .

After completion of the caulking operation, the inner diameter of the caulking portion, that is, the inner diameter of the fixed end 212, the durability of the inner ball joint assembly is reduced or the noise is generated while the driver does not drive the vehicle in the desired direction occurs Done.

That is, when the length of the inner diameter of the fixed end 212 formed by pressing pressing the upper portion of the ball housing 210 is formed smaller than the set length of the normal inner diameter, there is a problem that the durability of the inner ball joint assembly is reduced. .

In addition, when the inner diameter of the caulking portion, that is, the length of the inner diameter of the fixed end 212 is formed longer than the set inner diameter, the operating radius of the tie rod 200 provided with the ball member 201 becomes large and malfunctions when driving the vehicle. There was a problem that noise is generated as it occurs.

To solve this problem, after caulking, the inner diameter of the fixed end 212 provided in the ball housing 210 is measured using a calibrator 230 such as a vernier caliper after caulking as shown in FIG. 11. It is determined whether the range is set.

The conventional measurer 230 is formed to be elongated in the longitudinal direction, and is composed of a pair of movers 231 moved in the left and right directions along the side of the measurer 230.

Accordingly, the fixed end 212 moves the left and right directions in a state in which the mover 231 is in close contact with the inside of the fixed end 212 to fix the ball member 201 using a scale provided in the measurer 230. It is to measure the inner diameter of.

However, the problem of the conventional caulking unit inner diameter measuring device for the inner ball joint assembly is that the inner diameter of the stator 212 is measured by moving the pair of movers 231 in opposite directions so as to be in close contact with the inside of the stator 212. The problem that the internal diameter measurement of the fixed end 212 of the ball housing 210 constituting the ball joint assembly is not easy.

In addition, in order to measure the inner diameter of the fixed end 212 provided in the ball housing 210, one hand is holding the measurer 23, the other hand is fixed by moving the pair of movers 231 in the opposite direction to each other Since the inside diameter of the stage 212 is measured, the inside diameter of the fixed end 212 provided in the ball housing 210 not only becomes long because the measuring member 230 is shaken while measuring the inside diameter of the fixed end 212. Due to the lowered reliability of the measured value, there is a problem that the productivity is lowered.

And each time measuring the inner diameter of the fixed end 212, one hand is holding the measuring device, the other hand is easy to measure the inner diameter of the inner ball joint assembly because the mover 231 must move in the left and right directions There is a problem that can not be.

Accordingly, the present invention for solving the above problems is coupled to the rotary actuator consisting of a pair of rotating shaft, the fixed end for fixing the ball member when the front end of the rotary operating portion is rotated to both sides around the rotating shaft in the front of the rotary actuator Form a measuring part in close contact with the inner surface is bent in the front of the rotary actuator, and a variable resistor for generating an identifiable electrical signal by detecting the rotated angle of the measuring unit is formed in the lower portion of the rotary actuator to be connected to the lower end of the rotary shaft, And a display unit having a control unit for converting an electric signal input from a variable resistor into a unit of length and outputting a measurement value on one surface of the rotary operation unit to measure the inner diameter of the fixed end fixing the ball member. Inner Ball Joint Assemblies Made in Various Sizes It is easy to measure the inner diameter length of the fixed end provided in the measuring unit is set to zero the display unit in the state coupled to the zero adjustment jig provided with a plurality of jig grooves and then the measurement unit on the inner surface of the fixed end By closely determining whether the measured value output through the display part is within a predetermined error range, the measurement time of the inner ball joint can be significantly reduced, thereby improving the reliability of the measurement of the inner diameter length of the fixed end output through the display part. An object of the present invention is to provide an inner diameter measuring device for the caulking portion of a ball housing for an inner ball joint assembly that can improve the productivity of the inner ball joint assembly.

The present invention for achieving the above object,

In the inner measuring device for an inner ball joint assembly comprising a pressurized pressing caulk of the upper portion of the ball housing to form a fixed end for fixing the ball member coupled therein,

A pair of rotary actuators coupled to the rotary shaft and configured to have a front end rotated to both sides by an applied pressure;

" 모양으로 형성되는 측정부와; It is formed on the front surface of the rotary operation unit rotated to both sides and in close contact with the inner surface of the fixed end "

Measuring unit formed in a shape;

A variable resistor installed at a lower portion of the rotary actuator to be connected to a rotary shaft, the variable resistor generating different identification electrical signals according to a rotation angle of the measurement unit;

A control unit for converting the discriminating electric signal input from the variable resistor into a length unit signal;

And a display unit for outputting a length unit signal input from the control unit. The display unit outputs a length unit signal from the control unit. The display unit may measure whether the fixed end is fixing the ball member within a predetermined error range by using the measured value output from the display unit.

According to the present invention, the pair of rotation operation unit coupled to the rotation axis, the rotation operation of the measuring unit in close contact with the inner surface of the fixed end for fixing the ball member when the front end of the rotation operation unit is rotated about both sides of the rotation axis It is formed to be bent in the front of the part, and a variable resistor for sensing the rotated angle of the measuring unit to generate an identifiable electrical signal is formed in the lower portion of the rotary actuator to be connected to the lower end of the rotating shaft, the length of the electrical signal input from the variable resistor The display unit having a control unit for converting and outputting a unit is formed on one surface of the rotary operation unit to measure the inner diameter of the fixed end fixing the ball member as a single operation, and is manufactured in various sizes. It is possible to easily measure the fixed end of the inner ball joint assembly. It can be treated.

In addition, the measurement unit is set to zero the display unit in the state coupled to the zero adjustment jig provided with a plurality of jig grooves, the measurement unit is in close contact with the inner surface of the fixed end and the measured value output through the display unit exists in a predetermined error range Since it is possible to determine whether to do so, the effect of significantly reducing the measurement time of the inner ball joint can be expected.

And it is expected that the effect of improving the productivity of the inner ball joint assembly by improving the reliability of the measurement of the inner diameter length of the fixed end output through the display.

1 is an exploded perspective view of the inner measuring device for the inner ball joint assembly of the present invention.
Figure 2 is a perspective view of the combined inner measuring device for the inner ball joint assembly of the present invention.
3 is a partially enlarged cross-sectional view of an inner measuring device for an inner ball joint assembly of the present invention.
Figure 4 is an operating state of the inner measuring device for the inner ball joint assembly of the present invention.
5 is a perspective view showing a zero adjustment jig of the present invention;
Figure 6 is an operating state of the inner measuring device for the inner ball joint assembly of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to FIGS. 1 to 6 as follows.

First, prior to the description of the present invention, the description of the same reference numerals with respect to the same components as the prior art will be omitted.

According to the drawings, the present invention,

In the inner measuring device for the inner ball joint assembly comprising the step of forming a fixed end 212 for fixing the ball member 212 coupled to the inside by pressing and pressing the upper portion of the ball housing 210,

It is coupled to the rotary shaft 50, a pair of rotary operation unit 10 is a shear that is rotated to both sides by the pressure applied;

" 모양으로 형성되는 측정부(40)와; Is formed on the front surface of the rotary operation unit 10 rotated to both sides is in close contact with the inner surface of the fixed end 212 "

Measuring unit 40 formed in a shape;

A variable resistor 60 configured to be connected to the rotary shaft 50 at a lower portion of the rotary actuator 10 to generate different identification electric signals according to a rotation angle of the measurement unit 40;

A controller 70 for converting the discriminating electric signal input from the variable resistor 60 into a unit signal of length;

A display unit 80 for outputting a length unit signal input from the control unit 70; and using the measured value output from the display unit 80, the fixed end 212 is within a predetermined error range. Characterized in that configured to measure whether the fixed.

The rotatable operation portion 10 is formed to protrude on one surface in which the half disk-shaped rotation portions 31 and 31a face each other, and the fitting grooves 32 and 32a to which the rotation portions 31 and 31a are fitted. It is provided with the first working body 30 and the second working body (30a);

A first shaft hole 33 and a second shaft hole 33a respectively formed in the rotating parts 31 and 31a so that the rotating shaft 50 passes therethrough;

It is formed at the rear ends of the first working body 30 and the second working body 30a, respectively, so as to rotate the front ends of the first working body 30 and the second working body 30a around the rotating shaft 50 to both sides. Handle 35; and

The key groove 34 is formed on the inner surface of the first shaft hole 33 provided in the rotating part 31 of the first working body 30,

A key portion 51 corresponding to the key groove 34 is formed on the outer circumferential surface of the rotation shaft 50, so that the rotation shaft 50 is rotated in the direction in which the first working body 30 is rotated.

The display unit 80 is configured to be coupled to one side of the second working body (30a),

The lower portion of the display unit 80 is characterized in that the housing 62 is further provided with an insertion groove 63 for inserting the variable resistor 60 coupled to the lower end of the rotating shaft 50.

Connecting end 52 at the lower end of the rotating shaft 50 so that the variable resistor 60 for detecting the rotated angle of the measuring unit 40 to generate a different electrical signal having an identifying power is coupled to the lower end of the rotating shaft 50 Characterized in that formed more

Zero adjustment fixture 90 for controlling the rotation angle of the measuring unit 40 rotated to both sides about the rotation axis 50, and zero setting the display unit 80 in accordance with the rotation angle of the controlled measuring unit 40 Form more

The zero adjustment fixture (90) includes a base plate (100);

A pair of frames 101 installed vertically on an upper surface of the base plate 100;

Jig grooves 102 formed at equal intervals on one surface of the frame 101 facing each other;

Depth of the jig groove 102 is characterized in that each formed differently.

The present invention measures the inner diameter of the fixed end 212 formed by press-pressing caulking the upper portion of the ball housing 210 in one operation, and determine whether the measured value is within a predetermined error range to measure the inner ball joint assembly It is possible to improve the productivity of the inner ball joint assembly by reducing the measurement time and improving the reliability of the measured value measured on the inner diameter of the inner ball joint assembly.

1 to 4 show the inner measuring device for the inner ball joint assembly of the present invention, wherein the reference numeral 10 shows the rotary actuator 10.

The rotary operation unit 10 is formed in a pair as shown in Figure 1, the rotational configuration is coupled to the rotating shaft 50 so that the front end is rotated to open to both sides about the rotating shaft (50).

Rotating operation unit 10 in which the front end is rotated to be open to both sides around the rotation shaft 50 is composed of a first operating body 30 and the second operating body (30a) as shown in FIG.

Then, the semi-circular rotating parts 31 and 31a are projected alternately on one surface of the first working body 30 and the second working body 30a facing each other, and the rotating parts 31 and 31a are fitted. Grooves 32 and 32a are formed in the first working body 30 and the second working body 30a, respectively.

That is, as shown in FIG. 1, the rotatable portion 31 protrudes from the upper center to the middle of the first operating body 30, and is fitted in the center lower portion of the first operating body 30 to be positioned below the rotating unit 31. To form (32).

In addition, the rotation part 31 is alternately formed with the rotation part 31a protrudingly formed at the center lower portion of the second operation body 30a, and the fitting groove 32a into which the first rotation part 31 is fitted is formed in the second operation body 30a. It is formed on the upper surface of the first operating body 30 and the second operating body (30a) is coupled to the rotary parts 31, 31a are fitted respectively.

The first shaft hole 33 and the second shaft hole 33a are respectively provided in the rotating parts 31 and 31a coupled to the fitting grooves 32 and 32a of the first working body 30 and the second working body 30a. ) To couple the rotary shaft 50 to the first shaft hole 33 and the second shaft hole 33a.

A key groove 34 is formed on an inner surface of the first shaft hole 33, and a key portion 51 that is fitted into the key groove 34 to fix the rotation shaft 50 is formed on the outer circumferential surface of the rotation shaft 50.

In this case, the key groove 34 is formed on the inner surface of the second shaft hole 33, and the key groove 34 is not formed in the first shaft hole 33.

As such, since the first shaft hole 33 forms the key groove 34 into which the key part 51 provided on the rotation shaft 50 is fitted, the rotation shaft 50 is rotated in the direction in which the first working body 30 is rotated. Since the rotating shaft 50 is not rotated in the direction in which the second working body 30a is rotated, the front end of the first working body 30 and the second working body 30a may be rotated in opposite directions. The variable resistance 60 can detect the rotation angle of the measuring unit 40 which is rotated to be open to both sides due to the rotation of the first working body 30 and the second working body 30a.

The handle 35 is attached to the rear ends of the first working body 30 and the second working body 30a so as to rotate the first working body 30 and the second working body 30a in opposite directions. The measuring unit 40 is formed on the front surface of the first working body 30 and the second working body 30a.

At this time, the measuring unit 40 formed on the front surface of the first operating body 30 and the second operating body 30a is formed to be bent downward, so that the measuring unit 40 is formed by the pressure applied to the handle 35. ) To be open to both sides to facilitate contact with the inner surface of the fixed end (212).

The elastic spring 36 is coupled to the rear ends of the first working body 30 and the second working body 30a.

Therefore, the first working body 30 and the second working body 30a coupled to the rotation shaft 50 are pulled up and down as shown in FIG. 2 by the elastic force of the spring spring 36, and the rear end is rotated to both sides. It is possible to maintain the initial state of the state, by applying pressure to the handle 35 again, the front end of the first working body 30 and the second working body (30a) is rotated to both sides to open the measurement unit 40 The worker is able to repeatedly perform the work in close contact with the inner surface of the fixed end 212 with one hand.

When the measurement unit 40 is rotated to be open to both sides by the pressure applied to the handle 35, the rotating shaft 50 detects the rotated angle to generate different discriminative electric signals. ) Combining at the bottom of the configuration.

The lower end of the rotating shaft 50 forms a connection end 52 which is connected to the control terminal of the variable resistor 60, the variable resistor 60 coupled to the connection end 52 is the second body portion as shown in FIG. It is coupled to the upper surface of the housing 62 provided in the display unit 80 coupled to the side of the (30a).

As the connection terminal 52 rotating together with the rotating shaft rotates the control terminal of the variable resistor 60 in the forward and reverse directions, the resistance value of the variable resistor 60 is changed in proportion thereto, thereby identifying the controller 70. It outputs an electrical signal.

In the center of the upper surface of the housing 62 is formed an insertion groove 63 into which the variable resistor 60 is inserted, and the variable resistor 60 coupled to be inserted into the insertion groove 63 in the housing 62. The board 62 to be mounted is installed to be connected to the display unit 80 having the control unit 70 so as to detect a distinguished electric signal generated from the variable resistor 60 that senses the rotated angle of the measuring unit 40. The control unit 70 converts the length unit so that the measured value is displayed through the measuring unit 80.

In this case, the display unit 80 allows the measurement unit 40 to be in close contact with the inner diameter of the fixed end 212 in the zero state by the zero zero jig 90.

The zero zero jig 90 forms a base plate 100 as shown in FIG. 5, and a pair of frames 101 are placed on the upper surface of the base plate 100 so as to be spaced apart from each other.

In addition, a plurality of jig grooves 102 are formed on one surface of the frame 101 at the same price, and the jig grooves 102 have different depths.

To form the depth of the jig groove 102 differently, the ball member 102 provided in the tie rod 101 and the size of the ball housing 210 surrounding the ball member 102, respectively, according to the size of the vehicle Since it is manufactured differently, the depth of the jig groove 102 is formed differently so that the size of the fixed end 212 of the ball housing 210 manufactured in various sizes is measured in a zero setting state using one measuring device.

At this time, the jig groove 102 formed in the frame 101 reveals that it can be formed three or more as shown in the drawings, in the present invention three jigway grooves 102 different in depth as shown in the drawings This will be described as an example.

When explaining the preferred operating state of the present invention configured as described above is as follows.

First, after moving the measuring device to the top of the zero adjustment jig 90 provided with the jig groove 102, the operator grasps the handle 35 by hand so that the measurement unit 40 is in close contact with the jig groove 102 Add.

The measurement unit 40 is rotated to be open to both sides by the pressure applied to the handle 35, and the operator moves the zero switch 81 provided in the display unit 80 while being in close contact with the inside of the jig groove 102. By operating the display unit 80 is set to zero.

When the display unit 80 is set to zero, the measurer moves the measuring device as shown in FIG. 4A in the direction of the ball housing 210 to which the ball member 201 is coupled, and then is coupled to the ball housing 210. The inclined tie rod 200 in one direction.

Even when the tie rod 200 is inclined in one direction, the ball member 201 coupled to the coupling groove 211 of the ball housing 210 is ball housing 210 due to the fixed end 212 formed by pressing pressing caulking. It will be able to keep the state coupled to the inside.

When the tie rod 200 is inclined to one side in a state in which the tie rod 200 is coupled to the ball housing 210, the operator may handle the handle 40 to be in close contact with the measuring unit 40 inside the fixed end 212 as shown in FIG. Pressure).

The first working body 30 and the second working body 30a constituting the rotary operating unit 10 by the pressure applied to the handle 35 are lifted while the rear end is lifted about the rotating shaft 50. Rotates open to both sides.

The front end of the first working body 30 and the second working body 30a is rotated to be open to both sides and at the same time the rotating shaft 50 is rotated in the direction in which the first working body 30 is rotated measuring unit 40 Transfers the rotated angle to the variable resistor 60.

The variable resistor 60 receiving the rotational force of the rotating shaft 50 sends an identifying electric signal to the control unit 70, and the control unit 70 transmits the discriminating electric signal input from the variable resistor 60 in units of length. By changing the measurement unit 40 is rotated through the display unit 80 to output the measured value.

As described above with reference to FIGS. 5 to 9, the measurement value of the fixed end 212 is output using the zero adjusting jig 80 and the measuring device.

First, FIG. 5 illustrates that the depths of the jig grooves 102 are different from each other, and FIG. 6 illustrates a distance D1 between the jig grooves 102 formed at different depths while facing each other on one surface of the frame 101. It is shown that it is 25mm, 30mm, 35mm.

Therefore, in order to measure the fixed end 212 having an inner diameter of 25 mm, first, by applying pressure to the handle 35, the measuring unit 40 is in close contact with the inside of the jig groove 102 as shown in FIG. The zero switch provided in the display unit 80 is turned on to set the display unit 80 to zero.

When the display unit 80 is set to zero, the operator moves the measuring device to the ball housing 210d as shown in FIG. 4A and then applies pressure to the handle 35 as shown in FIG. The front end of the working body 30 and the second working body (30a) is rotated so as to open to both sides, the measuring unit 40 is in close contact with the inside of the fixed end 212 as shown in (b) of FIG.

At this time, the rotating shaft 50 is rotated at the same time in the direction in which the first operating body 30 is rotated to transmit the rotation angle rotated by the measuring unit 40 to the variable resistor 60, the variable resistor 60 is the identification force The electrical signal is sent to the controller 70, and the controller 70 in which the identified electrical signal is input is converted into units of length so as to be output through the display unit 80.

The tie rod 200 constituting the inner ball joint assembly is normally coupled to the ball housing 210 when the measured value output to the display unit 80 is within an error range of 0.1 to -0.1.

However, when the measured value output to the display unit 80 is out of the range of 0.1 to -0.1, which is an error range, the tie rod 200 constituting the inner ball joint assembly is outputted through the display unit 80 to the ball housing 210. Would be combined non-normally.

In order to measure the inner diameter of the fixed end 212 having an inner diameter of 30 mm, the measuring unit 40 is brought into close contact with the jig groove 102 formed of 30 mm as shown in FIG. After that, the measuring device is moved to the ball housing 210 to which the tie rod 200 is coupled.

When the measuring device is moved to the upper portion of the ball housing 210, the operator applies pressure to the handle 35 as shown in FIG. 4A, and the measuring unit 40 as shown in FIG. 8B has a fixed end 212. ) Make close contact with the inner surface.

When the measuring unit 40 is in close contact with the fixed end 212, the display unit 80 outputs the measured value in close contact with the fixed end 212, and the output value is 0.1 mm to −0.1 mm as described above. When outputting the value within, the tie rod 200 and the ball housing 210 is normally coupled, when the output value out of 0.1mm ~ -0.1mm tie rod 200 and ball housing 210 is non- Normally combined.

(A) and (b) of FIG. 8, the display unit 80 is set to zero after the measurement unit 40 is in close contact with the zero adjustment jig 90 formed at a distance of 35 mm. As shown in (a) shows the measurement of the inner diameter of the fixed end 212 after moving in the direction of the ball housing 210, detailed description will be omitted because the operator repeatedly performs the same operation.

10: rotary operating part, 30: first working body,
30a: second working body, 31, 31a: rotating part,
32, 32a: fitting groove, 33: first shaft hole,
33a: second shaft hole, 34: keyway,
35: handle, 36: spring spring,
40: measuring unit, 50: axis of rotation,
51: key part, 52: connecting end,
60: variable resistance, 61: substrate,
62: housing, 63: insertion groove,
70: control unit, 80: display unit,
90: zeroing fixture, 100: base plate,
101: frame, 102: jig groove,
200: tie rod, 201: ball member,
210: ball housing, 211: coupling groove,
212: fixed end,

Claims (5)

In the inner measuring device for the inner ball joint assembly comprising the step of forming a fixed end 212 for fixing the ball member 212 coupled to the inside by pressing and pressing the upper portion of the ball housing 210,
It is coupled to the rotary shaft 50, a pair of rotary operation unit 10 is a shear that is rotated to both sides by the pressure applied;
Is formed on the front surface of the rotary operation unit 10 rotated to both sides is in close contact with the inner surface of the fixed end 212 "

Measuring unit 40 formed in a shape;
A variable resistor 60 configured to be connected to the rotary shaft 50 at a lower portion of the rotary actuator 10 to generate different identification electric signals according to a rotation angle of the measurement unit 40;
A controller 70 for converting the discriminating electric signal input from the variable resistor 60 into a unit signal of length;
A display unit 80 for outputting a length unit signal input from the control unit 70; and using the measured value output from the display unit 80, the fixed end 212 is within a predetermined error range. Configure it to measure whether
The display unit 80 is configured to be coupled to one side of the second working body (30a),
An inner ball joint further comprising a housing 62 having an insertion groove 63 for inserting a variable resistor 60 coupled to a lower end of the rotation shaft 50 at the lower inner side of the display unit 80. Device for measuring inside diameter of caulking part of ball housing for assembly.
The method of claim 1, wherein the rotary operation unit 10,
The first working body 30 is provided with fitting grooves 32 and 32a in which the semi-circular rotating parts 31 and 31a are projected on one surface facing each other, and the rotating parts 31 and 31a are fitted. ) And a second working body (30a);
A first shaft hole 33 and a second shaft hole 33a respectively formed in the rotating parts 31 and 31a so that the rotating shaft 50 passes therethrough;
It is formed at the rear ends of the first working body 30 and the second working body 30a, respectively, so as to rotate the front ends of the first working body 30 and the second working body 30a around the rotating shaft 50 to both sides. Handle 35; and
The key groove 34 is formed on the inner surface of the first shaft hole 33 provided in the rotating part 31 of the first working body 30,
Inner ball joint assembly, characterized in that the key portion 51 corresponding to the key groove 34 is formed on the outer circumferential surface of the rotation shaft 50 so that the rotation shaft 50 rotates in the direction in which the first working body 30 is rotated. Internal measuring device for caulking part of ball housing.
delete The method according to claim 1,
The inner diameter measuring device of the caulking portion of the ball housing for inner ball joint assembly, characterized in that the lower end of the rotating shaft 50 is further formed connecting end 52 is fitted to the upper control end of the variable resistor (60).
The method according to claim 1,
Zero adjustment fixture 90 for controlling the rotation angle of the measuring unit 40 rotated to both sides about the rotation axis 50, and zero setting the display unit 80 in accordance with the rotation angle of the controlled measuring unit 40 Form more
The zero adjustment fixture 90,
A base plate 100;
A pair of frames 101 installed vertically on an upper surface of the base plate 100;
Jig grooves 102 formed at equal intervals on one surface of the frame 101 facing each other;
Depth (D) of the jig groove 102 is the inner diameter measuring device of the caulking portion of the ball housing for the inner ball joint assembly, characterized in that formed differently.

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