KR20050070746A - Gap measurement device of inner ring and outter ring of wheel bearing for vehicle - Google Patents

Abstract

The present invention relates to a measuring device for selecting a ball that meets the conditions of the wheel bearing by measuring the contact distance between the outer race and the ball race surface of the inner ring when assembling the wheel bearing for the vehicle, according to the first embodiment, In the device for measuring the displacement of the ball race formed on the outer ring of the bearing, it is arranged to face each other spaced in a straight line at a distance from the center of the outer ring of the bearing to be measured, each end face facing each other on the ball race surface of the outer ring An upper gauge tool and a lower gauge tool having a plurality of upper and lower cage balls rotatably circumferentially in contact therewith; A drive motor for rotating the lower gauge tool; An upper gauge tool moving cylinder for lowering the upper gauge tool to contact the upper gauge ball with the other ball race surface of the outer ring; A measurement connecting rod installed at a center of the upper gauge tool to be movable up and down by a spring force; It is characterized in that it comprises a measuring gauge that is in contact with the top of the measurement connecting rod to measure the micro displacement of the ball race surface. Therefore, it is possible to obtain a precise displacement without deviation by rotating the ball race surface.

Description

Gap measurement device of inner ring and outter ring of wheel bearing for vehicle}

The present invention relates to a measuring device for selecting a ball that meets the conditions of a wheel bearing by measuring the contact distance between the outer race and the inner race of the ball race when assembling the wheel bearing for automobiles, and in particular, by rotating the race surface of the ball precisely without deviation The present invention relates to a device for measuring the distance between the inner and outer rings of a wheel bearing for a vehicle in which displacement can be obtained.

A wheel bearing for automobiles is composed of one outer ring, two inner rings inserted into the outer ring, and a plurality of bearing balls located between the outer ring and each inner ring. At this time, the part where the bearing ball is in line contact is called a ball race.

Therefore, the outer ring has two ball races, and the inner ring has one ball race. The gap between the ball race in the outer and inner rings is a factor in determining the size of the ball. In general, the bearing ball is selected according to the conditions with the interval of the ball race measured in the outer ring and the inner ring. In general, bearing balls are classified with a difference of 2 to 5 microns.

Therefore, measuring the gap between the inner ring and the outer ring is a preliminary work to select the ball that meets the conditions by finding the degree of displacement of the ball race gap.

In the conventional method for measuring the distance between the inner ring and the outer ring, the average dimension in the circumferential direction according to the processing tolerances of the outer ring and the inner ring cannot be measured by measuring only the width of the ball race. That is, the measurement error is inevitable because the measurement is made only at the designated measurement position of any one ball race.

The present invention is to solve the problems of the prior art as described above, and to measure the average displacement in the circumferential direction while rotating the ball race between the outer ring and the inner ring to measure the distance between the inner ring and outer ring of the automotive wheel bearing The purpose is to provide.

The first embodiment of the present invention for achieving the above object,

In the device for measuring the displacement of the ball race formed on the outer ring of the wheel bearing for automobiles, in the center of the outer ring of the bearing to be measured to be spaced apart in a straight line at a predetermined interval to face each other, each side of the outer ring of the outer ring on the end side facing each other An upper gauge tool and a lower gauge tool having a plurality of upper and lower cage balls rotatable circumferentially to contact the race surface; A drive motor for rotating the lower gauge tool; An upper gauge tool moving cylinder for lowering the upper gauge tool to contact the upper gauge ball with the other ball race surface of the outer ring; A measurement connecting rod installed at a center of the upper gauge tool to be movable up and down by a spring force; It is characterized in that it comprises a measuring gauge that is in contact with the top of the measurement connecting rod to measure the micro displacement of the ball race surface.

According to a second embodiment of the present invention, in a device for measuring the displacement of a ball race formed on an inner ring of an automobile wheel bearing, a gauge tool having a gauge ball rotatable in contact with a corresponding ball race surface of a bearing inner ring to be measured and; A measurement connecting rod vertically mounted on a center line of the gauge tool and linked to vertical movement of the gauge tool; A measuring gauge contacting an upper end of the measuring connecting rod and measuring fine displacement of the ball race; A rotary shaft disposed below the center line of the gauge tool; A drive motor for rotationally driving the rotary shaft; It characterized in that it comprises a cylinder for operating the lifting shaft up and down.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4 is a device for measuring the outer ring spacing according to the present invention, Figure 1 is an overall configuration diagram of the outer ring spacing measuring device, Figure 2 is a state diagram when the upper cage tool of FIG. 3 is an enlarged view of a driving device for driving the lower gauge tool of FIG. 1, and FIG. 4 is a view showing a measurement state of the outer ring angle.

In the outer ring gap measuring apparatus according to the present invention, the upper gauge tool 10 and the lower gauge tool 40 are disposed to correspond to a straight line Z perpendicular to the base 1 as shown in FIGS. 1 to 4.

The upper gauge tool 10 has a plurality of upper gauge balls 14 circumferentially contacting the conical surface 12 at regular intervals, and the upper gauge ball 14 is bolted to the upper gauge tool 10. It is supported by the ball nest 16 attached.

The upper gauge tool 10 has a measuring connecting rod 18 inserted into the center thereof, and a measuring gauge 20 is disposed above the measuring connecting rod 18. At this time, the measurement gauge 20 is a kind of length displacement sensor (LVDT) is a precision measurement gauge that can measure a micron unit.

One end of the measuring connecting rod 18 is in contact with the inner engaging jaw 10a of the upper gauge tool 10 by a spring 22, and the measuring gauge 20 contacts the upper surface of the measuring connecting rod 18. It is.

The measuring connecting rod 18 is movably mounted in the sleeve 24 and the measuring gauge 20 is fixedly mounted on top of the sleeve 24. The sleeve 24 is fixedly mounted to the housing 26, which housing 26 is fixedly mounted to the bracket 3 receiving sliding guide support of the column 2 mounted on the base 1, (3) is connected to the rod of the pneumatic cylinder 28 disposed on the top of the column (2).

The upper gauge tool 10 is connected to and supported by a guide pin 30 on the housing 26, and the guide pin 30 is slidably inserted into the housing 26. Therefore, the guide pin 30 limits the downward movement of the upper gauge tool 10 and simultaneously guides the upward movement of the upper gauge tool 10 during the upward operation.

Accordingly, the upper gauge tool 10 moves up and down in accordance with the rod operating direction of the pneumatic cylinder 28.

The lower gauge tool 40 is rotatable by the drive motor 50 disposed below the base 1, and is lifted up by the cylinder 76.

The rotational force of the drive motor 50 rotates the pulley 54 through the belt 52, and the rotational force of the pulley 54 is supported on the bearing 56 so as to be rotatable on the centerline of the lower gauge tool 40. It is configured to rotate the shaft 58, the rotational force of the outer cylinder shaft 58 is configured to be transmitted to the inner cylinder shaft 62 fixedly mounted by the key 60 therein, the rotational force of the inner cylinder shaft 62 is the inner cylinder Arranged axially on the upper end of the shaft 62 to be transmitted to the coupling 66 mounted with the bolt 64, the rotational force of the coupling 60 is screwed to the housing 60 fixing pin 62 ) Is transmitted to the shaft portion 42 of the lower gauge tool 40.

The bearing 56 is installed in a bearing housing 57 fixedly mounted to the base 1.

The lower gauge tool 40 has a plurality of lower gauge balls 43 circumferentially contacting the conical surface 41 at regular intervals, and the lower gauge ball 43 is bolted to the lower gauge tool 40. It is supported by the ball nest 47 attached.

The lower gauge tool 40 is installed to be pulled downward by the force of the spring 44, the lower gauge tool 40 is movable up and down by the length of the fixing pin guide groove 42a formed in the shaft portion 42 It is.

A spline shaft 70 is disposed below one of the lower gauge tools 40 on one axis to spline the lower gauge tool 40 and is splined to the inner cylinder shaft 62, and the spline shaft 70 is disposed on the lower gauge tool 40. The lower end of is connected to the spline actuation cylinder 76 via the arm 74 while being supported by the bearing 72.

Therefore, when the action force of the spline operating cylinder 76 is operated downwards, the spline shaft 70 is lowered so that the upper surface of the spline shaft 70 is spaced apart from the lower surface of the shaft portion 42 of the lower gauge tool 40. On the contrary, when the acting force of the spline actuating cylinder 76 operates upward, the spline shaft 70 is raised (the spring 44 is compressed), and the upper surface of the spline shaft 70 is the lower gauge tool 40. The lower end surface of the shaft part 42 of () is pushed upwards.

The upper gauge ball 14 and the lower gauge ball 43 is composed of three to six.

The operation of measuring the displacement generated in the ball race of the outer ring configured as described above will be described.

The outer ring 100 to be measured is placed on the lower gauge tool 40 as shown in FIG. 1. Next, the upper gauge tool 10 is lowered toward the base 1 by the rod lowering operation of the pneumatic cylinder 28 and the lower gauge tool 10 is the spline shaft raised by the rod raising operation of the cylinder 76. In contact with 70, it moves upward.

Therefore, the two inner ball race portions of the outer ring 100 come into contact with the upper gauge ball 14 and the lower gauge ball 43, respectively, as shown in FIG.

In this state, the driving motor 50 is driven to reduce the contact between the gauge balls 14 and 43 and the ball race portion and the measurement error. The rotational force of the drive motor 50 is transmitted to the outer cylinder shaft 58 via the belt 52, and the outer cylinder shaft 58 rotates the coupling gauge 66 to rotate the lower gauge tool 40 in the same direction. Let's do it.

Accordingly, the lower gauge balls 14 and 43 rotate in the circumferential direction by the lower gauge tool 40 and at the same time the outer ring 100 is sandwiched between the upper and lower gauge balls 14 and 43 so that they rotate together.

At this time, the circumferential speed of the upper and lower gauge balls 14 and 43 is relatively faster than the rotational speed of the outer ring 100. Accordingly, the upper and lower gauge balls 14 and 43 find the correct ball race while passing evenly in the circumferential direction of the ball race portion of the outer ring 100.

After the rotation of the predetermined time the drive motor 50 is stopped and the ball race displacement of the outer ring 100 in the measurement gauge 20 is measured in units of microns.

That is, the displacement occurring in the ball race portion while the outer ring 100 rotates is transmitted to the measuring gauge 20 through the upper gauge tool 10 and the measuring connecting rod 18 so that displacement measurement is performed. The displacement amount of the ball race measured at the outer ring 100 is correlated with the displacement value obtained by the distance measuring device of the inner ring 100 ', which will be described later, to obtain a gap error of the ball race, thereby selecting a bearing ball having a desired condition. .

Figure 5 shows the overall configuration of the inner ring spacing device according to the invention, Figure 6 is an enlarged view of the upper gauge unit, Figure 7 is a state diagram of the inner ring spacing.

The inner ring spacing measurement according to the present invention is made by a measuring gauge 200 disposed above a straight line Z 'passing through the center of the inner ring 100' to be measured as shown in FIGS. At this time, the measurement gauge 200 is a type of length displacement sensor (LVDT) is a precision measurement gauge that can measure a micron unit.

An upper gauge tool 202 is disposed below the measurement gauge 200, and a measurement connecting rod 206 is interposed between the upper gauge tool 202 and the measurement gauge 200.

The upper gauge tool 202 has a plurality of upper gauge balls 208 circumferentially contacting the conical surface 202a at regular intervals, and the upper gauge ball 208 is bolted to the upper gauge tool 202. It is supported by the ball nest 212 attached.

One end of the measuring connecting rod 206 is supported by the spring 214 and is in contact with the measuring gauge 200.

The measuring connecting rod 206 is movably mounted in the sleeve 216, and the measuring gauge 200 is fixedly mounted on the top of the sleeve 216. The sleeve 216 is fixedly mounted to the housing 218, which is disposed at a certain height from the base 1.

The upper gauge tool 202 is connected to and supported by the guide pin 209 to the housing 218, and the guide pin 209 is slidably inserted into the housing 218. Accordingly, the guide pin 209 limits the downward movement of the upper gauge tool 202 and simultaneously guides the upward movement of the upper gauge tool 202 during the upward movement.

The inner ring support 230 is disposed in a straight line to face the center of the upper gauge tool 202, and the inner ring support 230 is rotationally driven by the drive motor 232 and at the same time the pneumatic cylinder 250. The lifting and lowering operation is performed.

The rotational force of the drive motor 232 rotates the pulley 236 through the belt 234, the rotational force of the pulley 236 is the outer cylinder supported by the bearing 239 installed in the bearing housing 237 of the base 1 It is configured to rotate the shaft 238, the rotational force of the outer cylinder shaft 238 is configured to be transmitted to the coupling 240 coupled to the spline shaft 242 and the spline therein, the coupling 240 The rotational force is to cause a rotational movement to the inner ring support 232 through the spline shaft 242, the spline shaft 242 is supported by a bearing 251 at the bottom and connected to the rod of the pneumatic cylinder 250 The lifting and lowering operation is performed through the arm 252.

Here, the gauge ball 208 was composed of three to six.

The gap measuring device of the inner ring 100 'configured as described above is made as follows.

First, when the inner ring 100 ', which is a specific object, is placed on the inner ring support 232, the pneumatic cylinder 250 operates to raise the cylinder rod, and the spline shaft 242 moves upward through the arm 252. The inner ring support 232 is moved to the upper gauge tool 202 side.

As a result, the ball race portion of the inner ring 100 'contacts the plurality of gauge balls 208 arranged on the circumference of the upper gauge tool 202 as shown in FIG.

Next, the drive motor 232 is rotated to reduce the complete contact and measurement error of the ball race portion between the gauge ball 208 and the inner ring 100 ', and the rotational force of the drive motor 232 is the outer cylinder via the belt 204. The shaft 240 and the coupling 240 are rotated, and the spline shaft 242 coupled to the coupling 240 rotates the inner ring support 232 so that the measurement object rotates the inner ring 100 '. .

After the rotation of the inner ring for a predetermined time, the driving motor 232 is stopped and the interval of the ball race is measured by the measuring gauge 200. In this case, the measurement gauge 202 receives the displacement generated in the ball race portion of the inner ring through the upper gauge tool 202 and the measurement connecting rod 206.

When the measurement is completed, the pneumatic cylinder 4 is returned to its original position, the inner ring support 232 is lowered and the measurement of the inner ring is completed.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

According to the present invention as described above, by contacting the three to six gauge balls in the ball race portion of the inner ring and the outer ring and rotating the inner ring or outer ring to be measured at a constant rotational speed by mounting the ball race portion and the gauge ball conventionally It is possible to improve the assembly quality of the wheel bearings by accurately selecting the bearing ball that meets the conditions.

The following drawings, which are attached in this specification, illustrate preferred embodiments of the present invention, and together with the detailed description of the present invention, serve to further understand the technical spirit of the present invention. It should not be construed as limited to.

1 is a block diagram of a device for measuring the outer ring spacing according to the present invention.

FIG. 2 is a state diagram when the upper cage tool of FIG. 1 is lowered. FIG.

3 is an enlarged view of a driving device for driving the lower gauge tool of FIG.

4 is a view showing a measurement state of the outer ring angle.

5 is a general configuration of the inner ring spacing measuring apparatus according to the present invention.

6 is an enlarged view of the upper gauge unit of FIG. 5.

7 is a measurement state diagram of the inner ring spacing.

<Explanation of symbols for the main parts of the drawings>

10: upper gauge tool

14,43: Gauge Ball

18: measuring connecting rod

20: measuring gauge

28: cylinder for moving the upper gauge tool

40: lower gauge tool

50: drive motor

70: spline shaft

76: cylinder

202: Gauge Tool

206: connecting rod

208: Gauge Ball

232; Drive motor

242: rotating shaft

250: cylinder

Claims (3)

In the device for measuring the displacement of the ball race formed on the outer ring of the wheel bearing for automobiles, Upper and lower cage balls (14) rotatable in a plurality of circumference to contact the ball race surfaces of both sides of the outer ring are arranged to face each other at a predetermined interval spaced in a straight line from the center of the outer ring of the bearing to be measured (14) An upper gauge tool 10 and a lower gauge tool 40 having 43; A drive motor 50 for rotating the lower gauge tool 40; An upper gauge tool moving cylinder (28) for lowering the upper gauge tool (10) to bring the upper gauge ball (14) into contact with the other ball race surface of the outer ring; A measurement connecting rod (18) installed at the center of the upper gauge tool (10) and movable up and down by a spring force; The measuring gauge 20 for measuring the fine displacement of the ball race surface in contact with the upper end of the measuring connecting rod (18), the gap measuring device of the inner and outer rings of the wheel bearing for automobiles. The method of claim 1, The lower gauge tool 40 is connected to the cylinder 76 and at the same time configured to be moved up and down by the spline shaft 70 receives the rotational force of the drive motor 50 Outer ring gap measuring device. In the device for measuring the displacement of the ball race formed on the inner ring of the wheel bearing for automobiles, A gauge tool 202 having a gauge ball 208 rotatable in contact with a corresponding ball race surface of a bearing inner ring to be measured; A measurement connecting rod 206 vertically mounted on a center line of the gauge tool 202 and linked to vertical movement of the gauge tool; A measuring gauge (200) contacting the upper end of the measuring connecting rod (206) to measure fine displacement of the ball race; A rotary shaft 242 disposed below a center line of the gauge tool 202; A drive motor 232 for rotationally driving the rotary shaft 242; Spacer measuring device between the inner ring and the outer ring of the wheel bearing for a vehicle, characterized in that it comprises a cylinder (250) for raising and lowering the rotary shaft (242).