KR101287483B1 - Circle diameter measurement device - Google Patents

Abstract

PURPOSE: A diameter measuring device is provided to conveniently measure a diameter of a large circle even though the size of the device is small and to improve the accuracy of the measurement as the diameter is automatically calculated by contacting the measurement legs onto the surface of the circle without manually operating the device by an operator. CONSTITUTION: A diameter measuring device (1) includes a body frame, a leg moving unit, a measuring position supporting unit, a rotation transfer supporting unit, a casing (500), and a control unit. The body frame supports the leg moving unit to be linearly moved in the left and right directions. The leg moving unit is moved in the left and right directions along an axial direction of the body frame and supports a pair of measurement legs (280). The measuring position supporting unit is arranged on the center of the body frame and supports a measurement position. The rotation transfer supporting unit supports the measurement legs to be rotated and moved to be parallel according to a shape of a target circle (A). The casing receives the body frame and protects the internal components thereof. The control unit calculates the diameter of the target circle according to the displacement of the leg moving unit.

Description

CIRCLE DIAMETER MEASUREMENT DEVICE

The present invention relates to a circular diameter measuring apparatus, and more particularly, to a circular diameter measuring apparatus capable of accurately measuring the diameter of a large circle.

Accurate measurement of the diameter of circular objects during mechanical manufacturing is an important factor in reducing tolerances and defects. To this end, a circle diameter measuring device capable of accurately measuring the diameter of a circular object is required.

In this regard, an internal and external diameter measuring apparatus is disclosed in Korean Laid-Open Application No. 1998-035655.

As described above, a method of measuring a circle diameter through a micrometer used to measure a circle diameter is known. In this case, the micrometer measures the diameter of the circle by directly contacting two axes to opposite points of the circle to be measured. That is, the fixed shaft is brought into contact with the first point, and the height of the movable shaft is adjusted by rotating the micrometer head. The moving shaft is adjusted to the left and right lengths to contact the second point.

The micrometer measures the diameter of the micrometer head when the positions of the fixed shaft and the moving shaft are fixed at two points.

However, since the conventional micrometer measures the diameter by directly contacting both points of the circle, in order to measure a large circle, the size of the micrometer can be measured because the size of the micrometer must be correspondingly large. In addition, since the operator directly rotates the micrometer head to move the position of the moving shaft to measure the diameter of the circle, when the diameter of the rotating object is measured, the operator is exposed to danger and the reliability of the measurement result is deteriorated. have. That is, there is a problem that a difference occurs in the precision of the circle diameter measured according to the skill of the operator.

When a difference occurs in the precision of the circle diameter, an additional problem may occur, in which an error occurs in the finished product to increase the defective rate.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-described problem, and to provide a circular diameter measuring device capable of easily measuring the diameter of a large circle even though the size is small.

Another object of the present invention is to provide a circular diameter measuring apparatus capable of improving the precision by automatically calculating the diameter by the contact of the circular surface, not the manual work of the operator.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

The object of the present invention can be achieved by a diameter measuring device. Circular diameter measuring apparatus of the present invention, the main body frame having a predetermined length; A pair of measuring legs having one end coupled to the main body frame and the other end tangentially contacting the surface of the measurement source, and spaced apart from each other at both ends of the main body frame; Leg moving unit for supporting the measuring leg to be moved left and right with respect to the main body frame; A measurement position support part provided in a center region of the main body frame and elastically moving up and down and supporting a measurement position of the measurement source; When the position of the measuring position support is fixed and the pair of measuring legs are moved left and right by the leg moving part and in contact with the measuring source, the displacement of the measuring leg is calculated and thereby the diameter of the measuring source. It characterized in that it comprises a control unit for calculating the.

According to one embodiment, the leg moving unit, the moving body coupled to the upper portion of the measuring leg; A feed guide shaft disposed along an axial direction of the main body frame and having a thread formed on a surface thereof; A shaft coupling nut for coupling the movable body and the transfer guide shaft such that the movable body moves linearly along the transfer guide shaft; It includes a drive unit for rotating the conveyance guide shaft.

According to an embodiment of the present invention, a nut insertion space in which the shaft coupling nut is coupled is formed in the moving body, and the nut insertion space includes an elastic member for elastically supporting left and right movement of the moving body; It is inserted into the elastic member, one end is fixed to the shaft coupling nut, the other end further comprises an elastic member guide shaft that is movably coupled through the moving body.

According to one embodiment, the scale bar is provided in parallel with the transfer guide shaft; The apparatus further includes a linear encoder provided in the mobile body to detect a movement displacement of the mobile body relative to the scale bar and transmit the detected displacement to the controller.

According to one embodiment, the measuring position support portion, and a case bracket coupled to the center region of the main body frame; A contact support plate provided below the case bracket and in contact with the outer periphery of the measurement source; A base protruding from the lower portion of the main body frame; A spring showbar which elastically supports the case bracket to move up and down; And a handle mount for pressing the base by an external force so that the base contacts the surface of the measurement source.

According to one embodiment, the body frame and the leg moving portion and the measuring position supporting portion therein further comprises a casing for exposing only the measuring leg and the contact support plate to the outside.

According to one embodiment, further comprises a centering bearing shaft coupled through the case bracket, the main body frame is independently aligned with the casing and the case bracket to maintain a perpendicular to the measurement surface of the measuring source. do.

According to one embodiment, it is provided on both ends of the main body frame further includes a rotation feed support for supporting the main body frame to be rotated and linear movement in the casing.

In the circular diameter measuring device according to the present invention, a pair of measuring legs are in contact with the surface of the measuring source and measure the diameter of the measuring source.

A pair of measuring legs Because the angle is placed, the overall volume can be reduced, and the diameter is measured electronically through the displacement of the measuring leg, so that the diameter can be measured accurately and precisely.

In addition, since the centering bearing shaft maintains a state perpendicular to the surface of the measuring source of the main body frame, it is possible to further increase the measurement accuracy.

In addition, since the moving body is elastically supported and moved by the elastic member, the load may be reduced during the movement to increase the product life.

1 is a perspective view showing a state in which the circular diameter measuring device of the present invention is located in a measuring circle;
Figure 2 is a perspective view showing the internal configuration of the casing of the diameter measuring apparatus of the present invention separated;
Figure 3 is an exploded perspective view showing a separate configuration of the diameter measuring apparatus of the present invention,
4a to 4d is an exemplary view showing a process of moving the leg moving portion of the circular diameter measuring apparatus of the present invention,
5 is a cross-sectional view showing a cross-sectional configuration of the measurement position support portion of the diameter measuring apparatus of the present invention;
6a and 6b is an exemplary view showing a center adjustment process of the measuring position support of the circular diameter measuring device of the present invention,
7A to 8 are exemplary views showing a measuring process of the device for measuring the diameter of the present invention.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Detailed descriptions of well-known functions and constructions which may be unnecessarily obscured by the gist of the present invention are omitted.

1 is an exemplary view showing a state in which the circular diameter measuring device 1 according to the present invention is disposed on an upper portion of a measuring source, and FIG. 2 is an internal configuration in which the casing 500 is separated from the circular diameter measuring device 1. 3 is an exploded perspective view showing an exploded configuration of the circular diameter measuring apparatus 1.

As shown, the circular diameter measuring apparatus 1 according to the present invention measures the diameter of the measuring source A by contacting a pair of measuring legs 280 to the surface of the measuring source.

To this end, the circular diameter measuring device 1 includes a main body frame 100 and a leg moving part 200 provided on both sides of the main body frame 100 so as to be movable to support the pair of measuring legs 280. Rotation which is provided in the center of the main body frame 100 to support the measurement position of the measurement source 300 and the measurement leg 280 to rotate and parallel move in accordance with the shape of the measurement source (A) The control unit 600 for accommodating the transfer support unit 400, the main body frame 100 to protect the internal configuration and the diameter of the measuring source A in accordance with the displacement of the leg moving unit 200 It includes.

The body frame 100 is provided in the form of a bar having a predetermined length. The body frame 100 supports the leg moving part 200 to be linearly moved from side to side. In addition, it is moved up and down by the measurement position support portion 300. The base 330 of the main body frame 100 is in contact with the surface of the measuring source A by the measuring position support unit 300 and the circular diameter is measured.

The body frame 100 is formed of a material having rigidity and durability. Both ends of the body frame is coupled to the rotational transfer support 400. The body frame 100 is moved back and forth by the rotation transfer support unit 400, it may be rotated around the rotation pin 440. The measurement position support part 300 is coupled to the center region of the main body frame 100.

The leg moving part 200 is provided to be movable left and right along the axial direction of the main frame 100 to support the measuring leg 280 to be moved according to the size of the measuring source (A). Leg moving unit 200 is provided between the moving body 210 and the measurement position support unit 300 and the face plate 410 is moved along the plate surface of the main frame 100 to guide the left and right movement of the moving body 210 Along the feed guide shaft 220, the shaft coupling nut 230 coupled to the feed guide shaft 220 so that the moving body 210 is moved along the feed guide shaft 220, along the feed guide shaft 220 A driving unit 260 for applying a driving force to move the moving body 210, a linear encoder 270 for measuring the movement displacement of the moving body 210, and a scale bar provided in parallel with the feed guide shaft 220 ( 275, a measuring leg 280 provided below the moving body 210, and a leg support frame 290 coupling the moving body 210 and the measuring leg 280.

4A to 4D are views illustrating a process and principle of moving the main body 210 along the main body frame 100.

The moving body 210 is movably coupled along the body frame 100. The moving body 210 is coupled to receive the body frame 100 therein. On the plate surface of the mobile body 210, a nut insertion space 211 to which the shaft coupling nut 230 is coupled is formed to a predetermined size.

The feed guide shaft 220 transmits the driving force of the driving unit 260 to the shaft coupling nut 230 so that the moving body 210 is moved left and right. A male screw thread of the feed guide shaft 220 is formed, and a female screw thread is formed on the inner circumferential surface of the shaft coupling nut 230. When the feed guide shaft 220 is rotated, the shaft coupling nut 230 is linearly moved left and right along the feed guide shaft 220 by the rotational speed of the feed guide shaft 220.

The feed guide shaft 220 is fixed at one end to the main frame 100 by the axial ring 221, and the other end is fixed to the screw fixing plate 420 of the rotary feed support 400.

An elastic member guide shaft 240 for guiding the front and rear movement of the shaft coupling nut 230 is formed in the nut insertion space 211 in parallel to the axial direction of the main frame 100. One end of the elastic member guide shaft 240 is fixed to the shaft coupling nut 230 and the other end is movably coupled through the side of the moving body (210). An elastic member 250 is coupled to an outer circumference of the elastic member guide shaft 240 to elastically support the left and right movement of the moving body 210 by the shaft coupling nut 230.

Since the elastic member 250 is fixed to the side wall forming the nut insertion space 211, the elastic member guide shaft 240 is compressed or extended when the elastic member guide shaft 240 moves in conjunction with the shaft coupling nut 230, and the left and right sides of the moving body 210 are fixed. This will help the movement and allow the measuring leg to reach the measuring surface of the circle to be measured with a constant force.

The driving unit 260 transmits the driving force of the driving motor 261 to the moving body 210. The driving unit 260 rotates in conjunction with the driving motor 261 generating the driving force, the driving pulley 263 coupled to the rotational shaft of the driving motor 261 and the driving pulley 263, and the feed guide shaft 220. Combined driven pulley 265, the drive pulley 263 and a driven belt (not shown) for connecting the driven pulley 265.

Here, the left and right pair of leg moving parts 200 are arranged in a direction in which the configuration of the main body frame 100 faces each other. That is, in the leg moving part 200 disposed on the left side, the transfer guide shaft 220 and the moving body 210 are disposed on the front surface of the main body frame 100, but the leg moving part 200 disposed on the right side of the leg moving part 200 includes a transfer guide shaft ( 220 and the moving body 210 is disposed on the back of the main frame 100. Since the driving motor 261 is located in the opposite direction to the feed guide shaft 220, the driving motor 261 is rotated by receiving a driving force by an electric belt (not shown).

The linear encoder 270 is coupled to the rear surface of the mobile body 210 and moved together with the mobile body 210. The scale bar 275 is disposed in parallel with the feed guide shaft 220. When the moving body 210 moves, the linear encoder 270 moving along the scale bar 275 calculates the movement displacement. The movement displacement calculated by the linear encoder 270 is transmitted to the controller 600, and the controller 600 calculates the diameter of the measurement source.

At this time, since the linear encoder 270 calculates the position in units of 1/1000, it is possible to more accurately measure the diameter of the measurement source (A).

A pair of left and right measuring legs 280 are coupled to the lower portion of the moving body 210 to be in contact with the outer circumference of the measuring source A in a tangential direction. The pair of measuring legs 280 according to the preferred embodiment of the present invention is coupled to the moving body 210 such that the angle between the interconnected virtual lines is 90 degrees. The lower portion of the moving body 210 is provided with a leg support frame 290 for supporting the position so that the measuring leg 280 is coupled at an inclined angle. Leg support frame 290 is fixed to the measuring leg 280 by the leg coupling bolt (281).

The angle formed by the pair of measuring legs 280 may be disposed at various angles as well as 90 degrees. When the angle is changed, the diameter can be obtained by changing the calculation formula of the controller 600.

The measuring position support part 300 supports the measuring position so that the diameter measurement can be accurately performed in a state where the diameter measuring device 1 is in close contact with the outer circumference of the measuring source A. The measurement position support part 300 is provided at the bottom of the case bracket 310, the case bracket 310, the contact support plate 320, which is in contact with the outer circumference of the measurement source A, and the bottom of the main frame 100. The base 330 protruding from each other, the show shaft shaft 340 protruding upward from the contact support plate 320, the spring shovel 360 coupled to the case bracket 310, and the spring shovel 360 mutually A spring showbar mount 350, a handle mount 370 pressurized by the user, and a centering bearing shaft 380 coupled to the case bracket 310 to adjust the centering of the case bracket 310.

5 is a cross-sectional view showing a planar cross-sectional configuration of the measurement position support 300. As shown, the case bracket 310 is coupled to the front and rear of the body frame 100. The case bracket 310 supports the casing 500 to be fixed when the casing 500 is coupled to the outside. The case bracket 310 elastically moves the main body frame 100 up and down along the show shaft 340 by pressing the handle mount 370 so that the base 330 contacts or is spaced apart from the measuring source A. do.

The contact supporting plate 320 is elastically coupled to the case bracket 310 by the showbar shaft 340, and is in close contact with the outer circumference of the measuring source A, so that the main body frame 100 is in contact with the side without falling down. Is maintained. To this end, the contact support plate 320 is preferably formed to have a predetermined curvature of a material having elasticity, such as a leaf spring.

The showbar shaft 340 is elastically variable in length depending on whether the upper region is coupled to the inside of the spring showbar 360 by the application of an external force through the handle mount 370. The base 330 is in contact with or is spaced apart from the surface of the measuring source A according to the change in the length of the showbar shaft 340.

The centering bearing shaft 380 couples the front and rear case brackets 310 and the main body frame 100 together. At this time, the centering bearing shaft 380 allows the body frame 100 to be moved independently of the casing 500 and the case bracket 310 fixed. That is, the centering bearing shaft 380 maintains the axis of the measuring surface of the measuring source A and the body frame 100 perpendicular to the casing 500 and the case bracket 310.

FIG. 6A is a schematic view comparing the case where the centering bearing shaft 380 is present with and without the circular diameter measuring device 1.

When the main frame 100 and the case bracket 310 are accommodated in the casing 500 without the centering bearing shaft 380, one side of the casing 500 is measured by the measuring source A for measuring the measuring source A. When the first contact with the main frame 100 is not in close contact with the measurement source (A) is measured in an inclined state.

On the other hand, if there is a centering bearing shaft 380, even if one side of the casing 500 is in contact with the measuring source (A) first, since the main frame 100 is independently centered by the centering bearing shaft 380 is measured It stands up perpendicular to the surface of the circle (A). Thus, accurate measurement is made.

As shown in FIG. 6B, the centering bearing shaft 380 maintains the body frame 100 perpendicular to the measurement source A regardless of the position of the measurement source A. FIG. In this case, the position alignment is performed independently regardless of the position of the casing 500.

The centering bearing shaft 380 is formed to be smaller than the diameter of the bearing shaft receiving hole (not shown) of the case bracket 310 and is rotatably provided inside the bearing shaft receiving hole (not shown). On the other hand, the centering bearing shaft 380 is formed in a size to be fitted to the bearing hole 315 of the main body frame 100 to allow the centering bearing shaft 380 and the main body frame 100 to move together.

The rotation feed support unit 400 supports the body frame 100 to be rotated or moved relative to the casing 500. The rotation feed support unit 400 includes a screw fixing plate 420 coupled to both ends of the body frame 100, a face plate 410 coupling the screw fixing plate 420 and the casing 500, and a body frame 100. Rotation bush 430 for supporting the pivot) and a rotation pin 440 coupled between the rotation bush 430 and the screw fixing plate 420.

The screw fixing plate 420 is coupled to both ends of the body frame 100 and rotatably fixes one end of the feed guide shaft 220. The rotating pin 440 is protruded from the plate surface of the screw fixing plate 420, and the rotating pin 440 is inserted into the rotating bush 430.

The rotating bush 430 has a pin moving space in which the rotating pin 440 can be linearly moved. The rotating pin 440 rotates inside the rotating bush 430 in order for the main frame 100 to be in close contact with the surface of the measuring source A by the action of the centering bearing shaft 380 according to the shape of the measuring source A. Or move straight. Rotating bush 430 is inserted into the coupling groove 413 formed in the plate surface of the face plate 410.

The face plate 410 is coupled to the rotating bush 430, it is coupled to both sides of the casing (500). Face plate 410 is exposed to the outside on both sides of the casing (500).

The casing 500 is fixed in position by the case bracket 310 and the face plate 410. In the upper portion of the casing 500, a see-through window 510 for visually confirming the position of the main body frame 100 is formed in a predetermined area. The pair of measuring legs 280 and the contact support plate 320 are exposed to the outside through the lower portion of the casing 500.

The control unit 600 calculates the diameter of the measurement source A through the displacement value of the moving body 210 measured by the linear encoder 270. The controller 600 calculates the displacement value as a diameter through a numerical program. The calculated diameter is displayed through a separate display unit (not shown) so that the user can easily check with the naked eye.

A process of measuring the diameter of the measurement source A using the circular diameter measuring apparatus 1 according to the present invention having such a configuration will be described with reference to FIGS. 1 to 8.

In the standby state before measuring the diameter of the left and right pairs of measuring legs 280 to maintain the open state to the outermost of the main frame 100. For the measurement, the user contacts the contact supporting plate 320 with the upper portion of the measurement source A as shown in FIG. 7A.

As the contact support plate 320 is in contact with the upper portion of the measurement source (A), the body frame 100 is balanced so as not to tilt. In this state, when the user presses the handle mount 370, the length of the showbar shaft 340 is shortened and the main body frame 100 is moved downward.

Accordingly, the base 330 of the lower portion of the main body frame 100 is in contact with the surface of the measurement source (A). At this time, the base 330 is in contact with the surface of the measurement source (A) horizontally by the action of the centering bearing shaft 380, the main frame 100 is in a state perpendicular to the measurement source (A). .

When the position of the base 330 is correctly fixed, the user applies power and the driving motor 261 is driven. The feed guide shaft 220 is rotated by the driving motor 261, and the shaft coupling nut 230 is moved along the feed guide shaft 220.

As shown in FIGS. 4A to 4D, the elastic member guide shaft 240 protrudes to the outside of the moving body 210 according to the transfer of the shaft coupling nut 230, and the elastic member 250 is inside the moving body 210. To be compressed. The moving body 210 gradually moves together with the shaft coupling nut 230 and the measuring leg 280 located below the moving body 210 also moves together.

When the measuring leg 280 gradually moves to contact the outer circumferential surface of the measuring source A as shown in FIG. 7B, the linear encoder 270 senses the position of the scale bar 275 at the current position and moves the moving body 210. Will be calculated. The calculated movement displacement is transmitted to the controller 600, and the controller 600 calculates the diameter of the measurement source A in the state of FIG. 8.

As described above, in the circular diameter measuring apparatus according to the present invention, a pair of measuring legs is in contact with the surface of the measuring source and measures the diameter of the measuring source.

Since the pair of measuring legs are arranged at an angle, the overall volume can be reduced, and the diameter can be measured electronically through the displacement of the measuring leg, so that the diameter can be measured accurately and precisely.

In addition, since the centering bearing shaft maintains a state perpendicular to the surface of the measuring source of the main body frame, it is possible to further increase the measurement accuracy.

In addition, since the moving body is elastically supported and moved by the elastic member, the load may be reduced during the movement to increase the product life.

The embodiment of the circular diameter measuring apparatus of the present invention described above is merely illustrative, and it is well understood that various modifications and equivalent other embodiments are possible to those skilled in the art. You will know. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

1: diameter measuring device 100: main frame
200: leg moving unit 210: moving body
211: Nut insertion space 220: Feed guide shaft
221: bearing ring 230: shaft coupling nut
240: elastic member guide shaft 250: elastic member
260 drive unit 261 drive motor
263: driven pulley 265: driven pulley
270 linear encoder 275 scale bar
280: measuring leg 281: leg coupling bolt
290: leg support frame 300: measuring position support
310: case bracket 315: bearing water
320: contact support plate 330: base
340: Showbar shaft 350: Spring Showbar Mount
360: Spring Shobar 370: Handle Mount
380: centering bearing shaft 381: bearing support plate
400: rotation feed support 410: face plate
413: coupling groove 420: screw fixing plate
430: rotating bush 440: rotary pin
500: casing 510: viewing window
600:

Claims (8)

In the diameter measuring device,
A main body frame having a predetermined length;
A pair of measuring legs having one end coupled to the main body frame and the other end tangentially contacting the surface of the measurement source and spaced apart from each other at both ends of the main body frame;
Leg moving unit for supporting the measuring leg to be moved left and right with respect to the main body frame;
A measurement position support part provided in a center region of the main body frame and elastically moving up and down and supporting a measurement position of the measurement source;
When the position of the measuring position support is fixed and the pair of measuring legs are moved to the left and right by the leg moving part and contacts the measuring source, the displacement of the measuring leg is calculated, and thus the diameter of the measuring source. It includes a control unit for calculating,
The measuring position support portion,
A case bracket coupled to a center region of the main body frame;
A contact support plate provided below the case bracket and in contact with the outer periphery of the measurement source;
A base protruding from the lower portion of the main body frame;
A spring showbar which elastically supports the case bracket to move up and down;
And a handle mount for pressing the base by an external force so that the base contacts the surface of the measuring source.
The method of claim 1,
The leg moving unit,
A moving body coupled to an upper portion of the measuring leg;
A feed guide shaft disposed along an axial direction of the main body frame and having a thread formed on a surface thereof;
A shaft coupling nut for coupling the movable body and the transfer guide shaft such that the movable body moves linearly along the transfer guide shaft;
Circular diameter measuring device comprising a drive unit for rotating the feed guide shaft.
The method of claim 2,
A nut insertion space is formed inside the moving body to which the shaft coupling nut is coupled.
The nut insertion space and the elastic member for elastically supporting the left and right movement of the moving body;
And an elastic member guide shaft inserted into the elastic member, one end of which is fixed to the shaft coupling nut, and the other end of which is movably coupled to the moving body.
The method of claim 3,
A scale bar provided in parallel with the transfer guide shaft;
And a linear encoder provided in the moving body to detect a movement displacement of the moving body relative to the scale bar and transmit the detected displacement to the controller.
delete The method of claim 1,
Accommodating the body frame, the leg moving part, and the measuring position support part therein;
And a casing which exposes only the measuring leg and the contact support plate to the outside.
The method according to claim 6,
And a centering bearing shaft coupled to the case bracket, the center frame being positioned independently of the casing and the case bracket to maintain a perpendicular state to the measurement surface of the measurement source. Diameter measuring device.
The method of claim 7, wherein
And a rotational transfer support part provided at both ends of the main body frame so that the main body frame can be rotated and linearly moved within the casing.

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