KR102019057B1 - An Electrolytic Corrosion Tester Of Bearing - Google Patents

Abstract

The rolling bearing test apparatus according to the present invention includes a device main body, a first support part and a second support part spaced apart from the device main body, a bearing installation part provided between the first support part and the second support part, and a first support part. And a rotation shaft supported by the second support part, the rotation shaft being inserted into the inner ring inner diameter of the test bearing, a driving part for rotationally driving the rotation shaft, and an electrode part for supplying electricity to the test bearing installed in the bearing mounting part;
The electrode part comprises a first electrode part connected to the inner ring of the test bearing installed in the bearing mounting part and a second electrode connected to the outer ring of the test bearing through the bearing mounting part; The first electrode part provides a rolling bearing electropneumatic test apparatus, characterized in that it comprises a circular electrode rotating part that rotates when the rotating shaft rotates to maintain contact.

Description

Roll Bearing Bearing Tester {An Electrolytic Corrosion Tester Of Bearing}

The present invention relates to a bearing electrical test apparatus, and more particularly to a bearing electrical test apparatus that can test the corrosion caused by the current generated in the bearing by rotating the drive while adding a current to the bearing.

Rolling element bearing is composed of a plurality of rolling elements which are provided in a plurality of spaced apart in the circumferential direction between the inner ring, the outer ring, and the inner ring and the outer ring to perform the rolling motion. The rolling bearing is further provided with a cage provided between the inner ring and the outer ring to maintain the circumferential distance of the rolling element, and a seal provided at an opening portion between the inner ring and the outer ring to prevent foreign matter from entering or leakage of lubricant. can do.

Rolling bearings are divided into ball bearings and roller bearings according to the rolling element type, and are provided as radial rolling bearings and thrust rolling bearings according to the supporting load direction.

Rolling bearings are used in devices such as divers machines, wheel sets, traction motors in rail vehicles, DC or electric vehicles used in drive trains, and generators driven by wind. These rolling bearings are exposed to electric current, which damages the outer ring, the inner ring, and the rolling element due to electric action, which causes premature failure of the motor or generator. In order to solve such a problem, a bearing having a current insulation performance may be used.

Conventionally, since there is no device for testing corrosion caused by current (hereinafter, referred to as 'formulae') that can predict rolling bearing life in a current environment, there is a problem in that data cannot be determined objectively.

Republic of Korea Publication No. 10-2013-0094226

The present invention has been proposed to solve the problems of the prior art as described above, and an object of the present invention is to provide a rolling bearing electrical test apparatus that can be driven and tested while adding current to the rolling bearing.

The rolling bearing test apparatus according to the present invention includes a device main body, a first support part and a second support part spaced apart from the device main body, a bearing installation part provided between the first support part and the second support part, and a first support part. And a rotation shaft supported by the second support part, the rotation shaft being inserted into the inner ring inner diameter of the test bearing, a driving part for rotationally driving the rotation shaft, and an electrode part for supplying electricity to the test bearing installed in the bearing mounting part;

The electrode part comprises a first electrode part connected to the inner ring of the test bearing installed in the bearing mounting part and a second electrode connected to the outer ring of the test bearing through the bearing mounting part; The first electrode part provides a rolling bearing electropneumatic test apparatus, characterized in that it comprises a circular electrode rotating part that rotates when the rotating shaft rotates to maintain contact.

In the above, the rotating shaft is made of a material that does not flow current; The first electrode part is a current-carrying bushing of a current-carrying material that rotates together with the rotation shaft and the inner diameter of the test bearing in contact with the inner diameter of the test bearing is inserted into the rotating shaft and the outer surface is installed in the bearing mounting portion, the first electrode body provided in the device body Done; The electrode rotating part is rotatably provided at one end of the first electrode body, and is rotated when the rotating shaft rotates in contact with the energizing bushing.

In the above, the bearing mounting portion is a '∩' shaped housing having an installation main body provided in the device body, a housing extension which is provided to be movable up and down along both sides of the installation main body, and the housing extension is fixed to the installation body It comprises a fixing means to make; A concave arc-shaped main body support part is formed in the upper part of the installation main body, and an arcuate housing support part is formed in the lower part of the installation housing to face the main body support part, and the outer ring of the test bearing installed in the bearing installation part is located above and below. It is characterized in that each pressurized by the body support and the housing support.

In the above, the lower portion of the installation main body is provided with a measuring means for measuring the load, the installation main body is provided with a pressing means for pressing up the measuring means, the installation main body by the pressing means while the load is measured by the measuring means It is characterized in that it is provided to be upwardly pressurized.

In the above, the lower portion of the first electrode body is further provided with an electrode buffer is provided to be movable in the vertical direction with respect to the first electrode body via the elastic member; The electrode buffer unit is characterized in that it is provided coupled to the device body.

In the above, the lower part of the first electrode body further includes an electrode adjusting unit; The electrode buffer portion further includes an electrode buffer adjusting portion which is open downward in the lower portion and is formed with a female thread, and an electrode body support portion having an electrode body adjusting portion in which the female thread is formed upwardly in the upper portion is further provided below the electrode adjusting portion. Coupled to the accessory device body;

 The electrode adjusting part includes a first adjusting part screwed to the electrode buffer adjusting part at an upper part, and a second adjusting part screwed to an electrode body adjusting part at a lower part thereof; When the electrode adjusting unit rotates, the distance between the electrode buffer unit and the electrode main body support unit is changed to adjust the height of the electrode rotating unit in the vertical direction.

Rolling bearing electrical test apparatus according to the present invention can test the corrosion caused by the current by driving while adding a current to the rolling bearing has the effect that can be collected data to objectively determine the corrosion caused by the rolling bearing current.

1 is a schematic perspective view showing a rolling bearing roll test apparatus according to the present invention,
FIG. 2 is a schematic side view of the rolling bearing electrical test apparatus shown in FIG. 1;
3 is a schematic cross-sectional view for explaining the rolling bearing electropneumatic test apparatus shown in FIG.
4 is an enlarged view of the energizing bushing and the first electrode part in FIG. 3;
5 is a partial cross-sectional view for explaining the bearing installation portion provided in the rolling bearing electrical test device of the present invention,
6 is a partial cross-sectional view for explaining the electrode portion provided in the rolling bearing electroforming test apparatus of the present invention.

Hereinafter, with reference to the accompanying drawings, it will be described in detail with respect to rolling bearing test apparatus according to the present invention.

1 is a schematic perspective view showing a rolling bearing roll test device according to the present invention, Figure 2 is a schematic side view of the rolling bearing roll test device shown in Figure 1, Figure 3 is a rolling bearing roll type shown in Figure 1 4 is a schematic cross-sectional view illustrating the test apparatus, and FIG. 4 is an enlarged view of the energizing bushing and the first electrode part in FIG. 3, and FIG. 5 is a diagram illustrating a bearing installation part provided in the rolling bearing electrical test apparatus of the present invention. FIG. 6 is a partial cross-sectional view for the purpose of describing an electrode part included in the rolling bearing electroforming test apparatus of the present invention.

In FIG. 3, the transverse direction is referred to as the "axial direction", the longitudinal direction as the "up and down direction", and the direction perpendicular to the ground is described as the "width direction".

As shown in Figures 1 to 3, rolling bearing electrical test device 100 according to the present invention is the device body 101, the first support 110, the second support 120, the bearing mounting portion 140, the rotation shaft 130, the driving unit 160, and the electrode unit 150.

The apparatus body 101 acts as a support frame of the rolling bearing test apparatus 100 according to the present invention, and a detailed description thereof will be omitted.

The first support 110 is provided on the upper portion of the device body 101.

The first support part 110 includes a first support body 111 and a first support bearing 115.

The first support body 111 is installed in the device body 101. The first support body 111 is provided in a plate shape extending in the vertical direction. The first support body 111 is formed with a through hole penetrated in the axial direction. The through hole is provided with a seating surface having a jaw surface and a circular cross section.

The first support bearing 115 is provided in a through hole of the first support body 111. The first support bearing 115 is provided seated on the mounting surface of the through hole.

The first support part 110 may further include a cover covering a radially outer side of the outer ring to prevent the first support bearing 115 from being separated from the jaw face.

An upper portion of the first support body 111 may be provided as a first coupling housing 113 that is detachable from the first support body 111. The first coupling housing 113 is formed in a “∩” shape so that a part of the through hole is detachably provided. The first coupling housing 113 is coupled to the first support body 111 by a coupling means.

The second support part 120 is provided above the device body 101. The second support part 120 is provided to be spaced apart from the first support part 110. The second support part 120 is provided side by side facing the first support part 110.

The second support part 120 includes a second support body 121 and a second support bearing 125.

The second support body 121 is installed in the device body 101. The second support body 121 is provided in a plate shape extending in the vertical direction. The second support body 121 has a through hole penetrated in the axial direction. The through hole is provided with a seating surface having a jaw surface and a circular cross section. The jaw surface formed on the second support body 121 is formed to face the jaw surface of the first support portion 110.

The second support bearing 125 is provided in a through hole of the second support body 121. The second support bearing 125 is provided seated on the mounting surface of the through hole.

The second support part 120 may further include a cover covering a radially outer side of the outer ring to prevent the second support bearing 125 from being separated from the jaw face.

An upper portion of the second support body 121 may be provided as a second coupling housing 123 that is detachable from the second support body 121. The second coupling housing 123 is formed in a “∩” shape so that a part of the through hole is detachably provided. The second coupling housing 123 is provided to be coupled to the second support body 121 as a coupling means.

Cylinders may be further provided below the first support 110 and the second support 120. A cylinder is provided below the first support part 110 and the second support part 120 so that the height of the first support part 110 and the second support part 120 can be adjusted according to the size of the test bearing T. do.

The bearing installation part 140 is provided between the first support part 110 and the second support part 140. The bearing installation part 140 is provided in parallel with the first support part 110 and the second support part 140.

As shown in FIG. 5, the bearing installation unit 140 includes an installation main body 141, an installation housing 143, a fixing means 145, a pressing means 149, and a measuring means 147. Is done.

The installation body 141 is provided on the upper portion of the apparatus body 101. The installation body 141 is provided in a plate shape extending in the vertical direction. The upper portion of the installation main body 141 is formed with a concave arc-shaped body support portion 1413. An arc angle of the main body support portion 1413 is formed smaller than 180 degrees. A lower concave groove is formed below the installation main body 141. The groove is provided with measuring means 147.

Body guide parts 1411 are provided at both sides in the width direction of the installation main body 141. The body guide part 1411 extends in the vertical direction. The body guide part 1411 serves as a guide in which the installation housing 143 is slidably movable in the vertical direction.

One or more installation body guides 1415 are provided below the installation body 141. The installation body guide part 1415 is provided in the shape of a rod extending downward in the lower portion of the installation body 141. The installation body guide part 1415 is provided spaced apart in the width direction or the axial direction from the groove formed in the lower portion of the installation body 141.

One or more device body guide portions 1011 are formed in the device body 101, which is a groove into which the installation body guide portion 1415 is slidably inserted. The apparatus body guide portion 1011 is formed at a position where the installation body guide portion 1415 is provided. The installation main body 141 is the installation main body guide portion 1415 is guided by the apparatus body guide portion 1011 and provided in the apparatus body 101 to move up and down.

The installation housing 143 is provided above the installation body 141. The installation housing 143 is formed in a '∩' shape. Both sides of the installation housing 143 in the width direction are provided with a housing extension part 1435 extending in the vertical direction.

Inside the housing extension part 1435, a housing guide part 1433, which is a groove extending in the vertical direction, is formed. The installation housing 143 is slidably inserted into the housing extension part 1435 so that the main body guide part 1411 is slidably moved upward and downward along both side surfaces of the installation main body 141.

An arc-shaped housing support part 1431 is formed below the installation housing 143 to face the main body support part 1413. The housing support part 1431 is formed between the housing extension part 1435. An arc angle of the housing support part 1431 is smaller than 180 degrees. The radius of curvature of the housing support part 1431 and the main body support part 1413 is formed to be the same size.

Since the arc angles of the housing support part 1431 and the main body support part 1413 are smaller than 180 °, a half radius of the outer diameter of the outer ring of the test bearing T is the radius of curvature of the main body support part 1413 and the housing support part 1431. A variety of test bearings (T) equal to or less than is possible.

The first coupling housing 113 of the first support part 110 and the second coupling housing 123 of the second support part 120 are formed in the same shape as the installation housing 143 to form the first support body 111. ) And the second support body 121 may be provided to be slidably moved, respectively.

The test bearing T is installed between the main body support portion 1413 of the installation main body 141 and the housing support portion 1431 of the installation housing 143. The outer ring of the test bearing T installed in the bearing installation unit 140 is provided by the main body support portion 1413 and the housing support portion 1431 at the top and bottom, respectively.

The housing support 1431 may further include an elastic member (not shown). As the elastic member is provided, the test bearing T is further provided to be stabilized.

The fixing means 145 serves to fix the housing extension 1435 to the installation main body 141. The fixing means 145 is provided with at least one screw hole is formed in the housing extension 1435 is screwed to the screw hole. The fixing means 145 may be made of a bolt whose end is pressed against the body guide portion 1411.

The pressing means 149 is provided below the installation body 141. The pressing means 149 may be formed of a cylinder that expands and contracts in the vertical direction. The test bearing (T) is provided by the pressing means 149 the installation main body 141 is pressed and fixed between the main body support portion 1413 and the housing support portion 1431.

The pressurizing means 149 may be installed to receive the groove by forming a concave groove in the device body 101.

The measuring means 147 is provided in the groove formed in the lower portion of the installation main body 141. The measuring means 147 is provided between the installation main body 141 and the pressing means 149. The measuring means 147 measures the load applied to the installation main body 141 by the pressing means 149. The measuring means 147 can be formed as a load cell for measuring the compressive load.

The rotation shaft 130 is provided in a rod shape extending in the axial direction. The rotating shaft 130 is made of a material in which no current flows, and is made of synthetic resin such as plastic.

The rotating shaft 130 is inserted into the inner ring inner diameter of the test bearing T, and both sides thereof are inserted into the inner ring inner diameter of the first support bearing 115 and the inner ring inner diameter of the second support bearing 125, respectively. Both sides of the rotation shaft 130 are axially supported by the first support part 110 and the second support part 120. When the rotation shaft 130 rotates, the inner ring of the first support bearing 115 and the inner ring of the second support bearing 125 rotate with the rotation shaft 130 integrally.

As shown in FIG. 2, the driving unit 160 is provided at one side of the rotation shaft 130. The driving unit 160 drives the rotation shaft 130 to rotate.

The drive unit 160 includes a shaft pulley 161 provided at one end of the rotation shaft 130, a motor pulley 165 provided at a motor shaft of the drive motor 167 installed at the apparatus main body 101, and the shaft pulley. 161 and the drive belt 163 wound around the motor pulley 165, and the drive motor 167 is provided in the apparatus main body 101.

When the drive motor 167 is rotated, the rotating shaft 130 is rotated, the inner ring of the test bearing (T) is driven to rotate.

As shown in FIG. 3, the electrode unit 150 supplies electricity to the test bearing T installed in the bearing installation unit 140. The electrode unit 150 is a passage through which current flows to the test bearing T.

The electrode unit 150 includes a second electrode 152 and a first electrode unit.

The second electrode 152 is connected to the outer ring of the test bearing (T) installed in the bearing mounting portion 140 through the bearing mounting portion 140. The second electrode 152 may be provided with a through hole formed in the bearing installation unit 140 or a groove formed on an outer surface thereof. The second electrode 152 may be provided in the form of a wire.

The first electrode portion is connected to the inner ring of the test bearing (T) is installed in the bearing mounting portion 140. The first electrode part includes an energization bushing 157, a first electrode body 151, and an electrode rotating part 153.

The energizing bushing 157 is made of an energizing material such as copper as a cylindrical hollow body. The rotating shaft 130 is inserted into the energizing bushing 157 is provided. The energizing bushing 157 is provided so that the outer surface is in contact with the inner diameter of the test bearing (T) installed in the bearing mounting portion 140 to rotate together with the inner diameter of the rotating shaft 130 and the test bearing (T).

In FIG. 2, reference numeral 1573 illustrates a bushing flange provided at one end of the energizing bushing 157 in an annular shape extending radially outward and in contact with one end of the inner ring of the test bearing T in the axial direction. Reference numeral 1311 illustrates a bushing support part that radially outwardly protrudes on the rotation shaft 130 between the bearing installation part 140 and the second support part 120 to be in contact with the other end of the energization bushing 157.

The other end of the energizing bushing 157 is provided in contact with the bushing support 1311. The bushing flange 1573 is provided to face the bushing support part 1311.

Opposite side of the bushing flange 1573 may be provided with an annular cap for supporting the outer ring of the test bearing (T) in the axial direction. The test bearing (T) may be installed stably by the cap is coupled to the installation housing 143 by a screw or the like.

The outer surface of the energizing bushing 157 is formed with a concave bushing groove 1571 along the circumferential direction. The cross section of the bushing groove 1571 may be formed in a “┌┐” shape. The bushing groove 1571 may be formed in a “∧” shape so that the cross sectional area becomes smaller toward the axial direction.

The first electrode body 151 is provided in the device body 101. The first electrode body 151 is made of a conductive material such as copper. The first electrode body 151 extends in the vertical direction. A branched branch 1511 is provided on the upper portion of the first electrode body 151 so that the cross section of the electrode body 151 is formed in a “Y” shape.

The electrode rotating part 153 is provided in a disc shape. The electrode rotating part 153 is provided between the branch parts 1511. The electrode rotating unit 153 is rotatably coupled to the branching unit 1511 to the electrode rotating shaft on both sides. The central axis of rotation of the electrode rotating unit 153 is provided in parallel with the central axis of rotation of the rotary shaft 130.

As shown in FIG. 4, the electrode rotating part 153 is provided with an edge inserted into the bushing groove 1571 to be in contact with the energizing bushing 157. The electrode rotating part 153 rotates together when the rotating shaft 130 rotates to maintain contact with the energizing bushing 157.

The electrode rotating part 153 is provided to maintain contact with at least two axial side surfaces of the bushing groove 1571. The electrode rotating part 153 is in contact with the energizing bushing 157 by maintaining contact with both sides of the axial direction of the bushing groove 1571 when a minute movement occurs in the axial direction, the width direction, and the vertical direction when the rotating shaft 130 is rotated. Is maintained.

As shown in FIG. 6, the first electrode body 151 may further include an electrode buffer 155. The electrode buffer 155 is made of a conductive material such as copper.

The electrode buffer 155 is provided below the first electrode body 151. The lower portion of the first electrode body 151 is formed with a downwardly open electrode body groove 1515. The electrode buffer 155 is slidably inserted into the electrode body groove 1513. An upper portion of the electrode buffer 155 is formed with a buffer groove 1553 upwardly open.

An elastic member 152 is installed in the space formed by the electrode body groove 1513 and the buffer groove 1553. The elastic member 152 may be, for example, a coil spring that is a conductive material. The elastic member 152 has an upper end in contact with the electrode body groove 1513 and a lower end in contact with the buffer groove 1553. The first electrode body 151 is provided to be movable in the vertical direction, the electrode rotating part 153 by the elastic member 152 is provided in pressure contact with the energizing bushing 157.

An electrode body supporter 157 and an electrode adjuster 159 may be further provided below the electrode buffer 155. An electrode buffer adjusting unit 1551 is formed in the lower portion of the electrode buffer 155 and downwardly opened and has a female screw.

The electrode body support 157 is provided spaced downward from the electrode buffer 155. The electrode body support 157 is provided coupled to the device body 101. The electrode body support part 157 is upwardly open at an upper portion thereof, and an electrode body adjusting part 1571 having a female thread is formed.

The electrode adjusting unit 159 is provided between the electrode buffer 155 and the electrode body support 157. The electrode adjusting unit 159 includes a first adjusting unit 1591 screwed to the electrode buffer adjusting unit 1551 at an upper portion thereof, and a second adjusting unit 1593 screwed to an electrode body adjusting unit 1571 at a lower portion thereof. The screw directions of the first adjusting part 1591 and the second adjusting part 1593 are formed in opposite directions.

When the electrode adjusting unit 159 is rotated, the distance between the electrode buffer 155 and the electrode body support 157 is changed to adjust the height of the electrode rotating unit 153 in the vertical direction.

The electrode adjusting unit 159 is provided with a hexagonal cross section between the first adjusting unit 1591 and the second adjusting unit 1593, and can easily adjust the height by rotating the portion with a tool such as a spanner.

The first electrode body 151 or the electrode buffer 155 may be coupled to the device body 101 via a length adjusting means such as a cylinder at the bottom to be capable of height adjustment in the vertical direction.

The first electrode part of the electrode unit 150 is connected to the positive electrode (or negative electrode) of the power supply, and the second electrode 152 is connected to the negative electrode (or positive electrode) of the power source. A switch is provided to control the first electrode part with the power source or the second electrode 152 with the power source. The first electrode part is electrically connected to the inner ring of the test bearing T, and the second electrode 152 is electrically connected to the outer ring of the test bearing T so that the test bearing T is energized.

The bearing installation unit 140 of the rolling bearing electrical test device 100 according to the present invention is provided with a vibration sensor (not shown). The vibration sensor checks whether the test bearing (T) is damaged by measuring the vibration of the test bearing (T) generated when a current flows through the test bearing (T) and the bearing rotates. By checking the vibration measured by the vibration sensor it is possible to check the life of the rolling bearing.

The rolling bearing electrical test apparatus according to the present invention has been described with reference to the embodiments shown in the drawings, but this is merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible. . Therefore, the true technical protection scope should be defined by the technical spirit of the appended claims.

100: rolling bearing electrical test device
101: device body 110: first support portion
120: second support portion 130: rotation axis
140: bearing mounting portion 150: electrode portion
160: drive unit

Claims (6)

It is provided between the device body 101, the first support portion 110 and the second support portion 120 provided to be spaced apart from the device body 101, the first support portion 110 and the second support portion 120 Rotating support is supported by the bearing installation unit 140, the first support 110 and the second support 120, the rotary shaft 130 is inserted into the inner ring inner diameter of the test bearing (T), and the rotary shaft 130 A drive unit (160) for driving rotation and an electrode unit (150) for supplying electricity to the test bearing (T) installed in the bearing installation unit (140);
The electrode unit 150 is connected to the outer ring of the test bearing T through the first electrode unit and the bearing mounting unit 140 connected to the inner ring of the test bearing T installed in the bearing mounting unit 140. An electrode 152; The first electrode part includes a circular electrode rotating part 153 which rotates when the rotating shaft 130 rotates to maintain contact;
The rotating shaft 130 is made of a material that does not flow current; The first electrode part is a current-carrying material that is rotated with the inner diameter of the rotating shaft 130 and the test bearing (T) in contact with the inner diameter of the test bearing (T) is inserted into the rotating shaft 130 and the outer surface is installed in the bearing mounting portion 140 An energizing bushing 157 and a first electrode body 151 provided in the apparatus body 101; The electrode rotating unit 153 is rotatably provided at one end of the first electrode body 151, the rolling bearing electrical test device, characterized in that when the rotating shaft 130 rotates in contact with the energizing bushing (157). delete According to claim 1, wherein the bearing mounting portion 140 is an installation body 141 provided in the device body 101, and a housing extending portion provided to be slidable up and down along both sides of the installation body 141 ( It includes a '∩' type installation housing 143 having a 1435, and a fixing means 145 for fixing the housing extension 1435 to the installation main body 141; A concave arc-shaped main body support part 1413 is formed on the upper part of the installation main body 141, and an arc-shaped housing support part 1431 is formed on the lower part of the installation housing 143 to face the main body support part 1413. And, the outer ring of the test bearing (T) is installed in the bearing mounting portion 140 is rolling bearing electrical test device, characterized in that the pressurized by the main body support portion (1413) and the housing support portion (1431), respectively. According to claim 3, wherein the lower portion of the installation main body 141 is provided with a measuring means for measuring the load, the installation main body 141 is pressurizing means 149 for pressing the measuring means 147 upwardly Is provided, the installation body 141 is rolling bearing electrical test device characterized in that the load is measured by the measuring means (147) is provided to be upwardly pressurized by the pressing means (149). According to claim 1, The lower portion of the first electrode body 151 is further provided with an electrode buffer 155 is provided to be movable in the vertical direction relative to the first electrode body 151 via the elastic member 152. Provided; The electrode buffer unit 155 is rolling bearing electrical test device, characterized in that provided with the device body 101 is provided. The method of claim 5, wherein the lower portion of the first electrode body 151 further comprises an electrode adjusting unit (159); The electrode buffer 155 is provided with an electrode buffer adjusting unit 1551 downwardly open at the lower portion and formed with a female thread, and an electrode body adjusting unit 1571 is formed at the lower portion of the electrode adjusting unit 159 with an female thread formed at an upper portion thereof. An electrode body support 157 is further provided, and the electrode body support 157 is coupled to the apparatus body 101;
The electrode adjusting unit 159 includes a first adjusting unit 1591 screwed to the electrode buffer adjusting unit 1551 at an upper portion thereof, and a second adjusting unit 1593 screwed to an electrode body adjusting unit 1571 at a lower portion thereof; Rotating the electrode adjuster 159, the distance between the electrode buffer 155 and the electrode body support 157 changes the vertical bearing height rolling device characterized in that the vertical height of the electrode rotating unit 153 is adjusted.

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