KR101170898B1 - Displacement measure device - Google Patents

Abstract

PURPOSE: A device for measuring displacement is provided to easily perform a loading test of a structure and to reduce the generation of errors of a displacement value being measured. CONSTITUTION: A device for measuring displacement comprises a support stand(41), a displacement meter(42), a case(43), a supporting plate(44), an elastic body(45), and a guide rod. The lower part of the supporting stand is supported on the ground and a height of the supporting stand is upwardly adjusted. The displacement meter is mounted on the supporting stand. The case is installed in the upper part of the displacement meter and supported by the supporting stand. The supporting plate is supported to the case in the upper part of the case and has a movement range corresponding to the displacement of an upper structure directly supporting the load of the upper part of a structure. The elastic body upwardly supports the supporting plate with self-elasticity. The upper part of the guide rod is fixed to the supporting plate and guides the movement of the supporting plate.

Description

Displacement measure device

The present invention relates to a displacement measuring apparatus, and more particularly, to a measuring apparatus for measuring displacement for analyzing the superstructure behavior of a structure to be tested while being supported upward during the load test of the structure.

Structures such as buildings and bridges can be loaded and tested for safety by analyzing the behavior of superstructures. In the case of structures such as buildings, safety can be reviewed by analyzing the behavior of beams forming the superstructure, and structures such as bridges can be reviewed for safety by analyzing the behavior of girders, etc. forming the superstructure. .

In particular, a bridge refers to a facility that traverses a river or canyon, river, sea, road, etc. as one of road facilities, and the bridge may be divided into a superstructure and a substructure.

The upper structure of the bridge is a portion that directly supports the load generated from the upper side is composed of a slab and girder, and the lower structure is shifted to perform the role of transferring the load transmitted from the upper structure to the ground while supporting the upper structure. , Pier and foundation.

The bridge receives a continuous load by passing by itself or by a vehicle or a pedestrian, and such a load receives more loads as time passes, so that the aging phenomenon of the superstructure proceeds in a bridge under continuous load.

As such, if the aging of the superstructure continues, there is a possibility that the bridge may be damaged, damaged, or settled by accumulated fatigue, and there is a risk of large accidents such as the collapse of the bridge. Diagnosis is essential.

The bridge is provided with a device capable of measuring the structural behavior of the superstructure of the bridge, for example, deformation, inclination, settlement, cracking, and the like, so as to determine the safety of the bridge by measuring the behavior of the superstructure.

If a device capable of measuring the behavior of the bridge is not installed in the superstructure of the bridge, the behavior of the superstructure cannot be measured, and if the measurement of the behavior of the superstructure is not made, the upper Factors affecting the safety of the entire bridge structure, such as structural deformation, slope, settlement and cracking, are seriously progressed, so that the cause of the bridge collapse cannot be identified.

In addition, the integrity of the bridge is confirmed by a load test or the like to confirm the current surface state of the superstructure, this load test is a method of the test carried out for the purpose of quantifying the actual load capacity of the bridge.

The load test is a test that observes and measures the actual behavior of the main members of the bridge by loading a known load directly within a specific area of the bridge according to the prescribed regulations. The result is evaluated by the theoretical method. It becomes the data to supplement the load capacity of the bridge.

On the other hand, the Republic of Korea Patent No. 10-0762285 relates to a split type fixing device of the ring-type deflection meter for safety diagnosis, the registered patent is easy to install and precise data regardless of the height of the bridge and the topographic conditions of the bridge An invention is disclosed for a split lock of a ring type deflection meter for safety diagnosis.

The patent has a fixing magnetic holder installed in the upper mold between the bridge and the bridge of the bridge and the lower half of the slab; A steel wire formed vertically downward on one end of the fixing magnetic holder and having a ring type deflection meter on one end of the body; A split fixing part for fixing the ring-type deflection system to the body part and having three legs adjustable up, down, left and right according to the terrain; Disclosed is a split type fixing device of a ring-type deflection system for safety diagnosis, comprising first, second, and third split fixing plates, each of which fixes the legs of the split fixing part and is fixed to the ground.

SUMMARY OF THE INVENTION An object of the present invention is to provide a displacement measuring device capable of measuring displacement during loading tests for analyzing the superstructure behavior of a structure under poor test conditions.

Another object of the present invention is to provide a displacement measuring device capable of measuring displacement by positive and dynamic loads during load testing while supporting the upper surface of the upper structure of the structure upward.

Displacement measuring device according to the present invention, the lower end is supported on the ground, the support can be adjusted in height upward; A displacement meter mounted to the support; A case positioned above the displacement gauge and supported by the support; A support plate supported on the case at an upper side of the case and having a moving range corresponding to displacement of the superstructure directly supporting the upper load of the structure; An elastic body for supporting the support plate upward by its elasticity; And a guide rod having an upper end fixed to the support plate to guide the movement of the support plate. It is configured to include.

Displacement measuring device according to the present invention is configured to support a portion having a moving range corresponding to the displacement of the structure upwards, it is configured to enable the measurement of the displacement during the load test for analyzing the structural behavior of the structure.

Therefore, the effect of easy installation of the measuring device for measuring the displacement during the load test of the structure can be expected, the effect that can be easily carried out the load test of the structure can be expected.

In addition, the loading test of the target structure can be expected to be less affected by the loading test for the analysis of the behavior of the upper structure of the structure, accordingly, it can be expected to reduce the error occurrence for the measured displacement value .

As the error of the measured displacement value is reduced, the accuracy of the measured displacement value can be expected to be improved, and the accurate displacement value can be measured, so that the effect of accurately quantifying the actual load capacity of the structure can be expected. do.

In addition, by being able to accurately measure the load capacity of the structure it is possible to expect the effect of accurately determining the progress of the factors affecting the safety of the structure, such as deformation, slope, settlement and cracking of the structure.

By accurately determining the progress of the factors affecting the safety of the structure as a whole, it is possible to expect the effect that can ensure the health of the current state of the structure.

1 is a side view showing the external appearance of the bridge is installed displacement measuring apparatus according to an embodiment of the present invention.
Figure 2 is a partial cutaway showing the configuration of the bridge is installed displacement measuring apparatus according to an embodiment of the present invention.
Figure 3 is a perspective view showing the external appearance of the displacement measuring apparatus according to an embodiment of the present invention.
Figure 4 is an exploded perspective view showing the internal configuration of the displacement measuring apparatus according to an embodiment of the present invention.

Hereinafter, the configuration of the displacement measuring apparatus according to the present invention is installed on the bridge to measure the displacement for analyzing the behavior of the bridge, for example, with reference to the accompanying drawings.

However, the spirit of the present invention is not limited to the implementation state by the embodiments described below, and those skilled in the art to understand the spirit of the present invention using other embodiments falling within the scope of the same technical spirit It may be easily proposed, but this will also be included in the technical idea of the present invention.

In addition, terms used in the present specification or claims are concepts selected for convenience of description, and in grasping the technical contents of the present invention, they should be appropriately interpreted as meanings corresponding to the technical idea of the present invention.

1 is a side view showing the external appearance of the bridge is installed displacement measuring apparatus according to an embodiment of the present invention, Figure 2 is a partial cutaway showing the configuration of the bridge is installed displacement measuring apparatus according to an embodiment of the present invention.

The load test is divided into static and dynamic load tests. After selecting the load test span, the type of sensor and measuring device and the attachment location are determined according to the structure type and the purpose of measurement of the target structure. It is equipped to measure bending strain, shear strain, maximum deflection, vibration and dynamic properties, cracking behavior and so on.

These load tests are carried out in the most vulnerable span depending on the condition of the bridge when selecting the static and dynamic load test spans for the evaluation of the load capacity of structures such as bridges.

Referring to FIGS. 1 and 2, the bridge 1 includes an upper structure 2 that directly supports a load of a vehicle, and a lower structure 3 that supports a load of the upper structure 2. .

The upper structure (2) is formed in the form of a slab (21, Slab) is a planar member that is configured to have a large area for the movement of the vehicle is subjected to the vertical load, and the beam supporting the slab 21 from the lower side It has a configuration including a girder 22.

The substructure 3 includes a pier coping portion 31 for supporting the girder 22 from below, a pier pillar portion 32 for supporting the pier coping portion 31 from below, and the pier pillar 32 It is configured to include a base 33 for transmitting the load transmitted from the ground to the ground.

Displacement measuring device 40 of the bridge according to the present invention is mounted on the girder 22 positioned relatively lower in the upper structure (2). The displacement is generated in the slab 21 which is subjected to the vertical load, the displacement generated in the slab 21 is transferred to the girder 22 is installed the measuring device 40 in the girder 22 The displacement of the bridge 1 is measured.

The measuring device 40 may be configured to be installed in a plurality of points on the lower side of the girder 22, it is also possible to be installed at any one point to measure the displacement of the bridge (1).

Hereinafter, the measuring device will be described in detail with reference to FIGS. 3 to 4. 3 is a partial side cross-sectional view showing a mounting state of the displacement measuring apparatus according to an embodiment of the present invention, Figure 4 is an exploded perspective view showing the internal configuration of the displacement measuring apparatus according to an embodiment of the present invention.

Referring to these drawings, the displacement measuring apparatus 40 according to the present invention has a lower end portion supported on the ground, the height of which can be adjusted upward, and a displacement meter 42 mounted to the support 41. And a case 43 positioned above the displacement meter and supported upward by the support 41, and an upper structure directly supported by the case 43 above the case 43 and directly supporting an upper load of the structure. A support plate 44 having a moving range corresponding to the displacement of the support plate, an elastic body 45 supporting the support plate 44 upward by its elasticity, and an upper end portion thereof fixed to the support plate 44, It comprises a guide rod 46 for guiding.

The support 41 is formed in a cylindrical shape long in the vertical direction while having a certain diameter. The lower end of the support 41 is supported on the ground surface located below the bridge 1 or the bottom surface of the water, and is formed of a material having a certain strength as a whole, so that the case 43 and the elastic body 45 It can be supported upward.

Of course, the support 41 may be configured in a form other than the cylindrical form. For example, a square pillar or a hexagonal pillar may be possible.

However, since the shape of the cylinder is the shape that is least affected by the environment of the outer space, that is, the fluid flowing under the bridge (1), the configuration formed in the form of a cylinder will be preferable.

In the lower half of the support 41, an auxiliary support 415 is mounted to support the support 41 to the ground or the bottom of the water. The auxiliary support 415 is located in the upper end of the auxiliary fixing part is fixed to the support 41 and the fixed, the lower end is located on the ground in the state that the upper end is rotatably fixed to the outer surface of the auxiliary fixing part It is configured to include an auxiliary support for generating an auxiliary support force of the support (41).

At least two auxiliary supports 415 are provided to improve the supporting force of the support 41, and preferably, the auxiliary support 415 is provided with three or more upper ends to the support 41 Is fixed to the lower end is located on the ground to improve the support of the support (41).

In the embodiment of the present invention, three auxiliary supports 415 are provided to improve the supporting force of the support 41 and look at the configuration for supporting the support 41, for example. In this case, the auxiliary support 415 is spaced by the same distance, respectively, it is possible to support the support 41 more stably.

A fixing plate 411 for supporting the lower end of the support 41 may be installed on the ground surface or the bottom surface of the water supporting the lower end of the support 41. The fixing plate 411 is formed in the shape of a square plate having a predetermined thickness, and the fixing protrusion inserted into the lower end of the support 41 is protruded upward in the center of the upper surface.

The support 41 is fixed in a state where the fixing protrusion is inserted into an inner space of the lower end of the support 41 through the open lower surface of the support 41 so that the lower end of the support 41 is located on the ground surface or the bottom of the water. Is supported on the side.

In addition, the support 41 is configured to be height adjustable upward. This may be possible in the case of being configured to be able to adjust the height in a configuration for connecting a plurality of supports 41 having a certain length, the plurality of the support 41 having a different diameter in the inner space accommodated in the state accommodated It may be configured to be able to adjust the height by fixing while pulling out the support (41).

According to an embodiment of the present invention, a configuration capable of adjusting a height suitable for the bridge 1 to measure displacement by extracting and fixing the support 41 accommodated in a state where a plurality of the support 41 is accommodated in an internal space is provided. An example will be described.

In this case, the plurality of the support 41 may be configured to have a cylindrical shape having the same diameter, different diameters, that is, one end portion having a rather long diameter, while the other end portion has a relatively short diameter It may also be configured to have.

The support 41 is configured to easily adjust the height in any case, the fixing member 412 for fixing the adjacent support 41 is provided at the portion to which the support 41 is connected.

The fixing member 412 is formed on the outer surface of the support portion 41, the movement portion 414 to penetrate or pull through the support 41 and rotates by the user's operation, and coupled with the movement portion 414 It comprises a fixing part 413 for fixing the support (41).

The movement part 414 is further provided with a handle so as to be easily manipulated by the user, the outer surface of the movement part 414 is formed with a screw thread for engagement with the fixing part 413 while rotating, the fixing part 413 The inner surface of the thread is formed for coupling with the outer surface of the moving part 414.

In addition, a fixing hole is formed on an outer surface of the support 41 to allow the movement part 414 to rotate into or out of the inner space of the support 41. The movement part 414 is coupled to the fixing part 413 while rotating, and is introduced into the internal space of the support 41 while passing through the fixing hole, and an end portion thereof is located in the internal space of the support 41. In contact with the outer surface of the other support 41 to be compressed.

The support 41 which is pressed while contacting the end of the movement part 414 is fixed while the movement in the vertical direction is limited in the inner space of the support 41 located on the outside.

When one fixing member 412 is formed, one fixing hole is formed at an outer surface of the support 41, and the fixing unit 413 is coupled to the moving unit 414 in a state where the fixing unit 413 is fixed to the outside of the support 41. The moving part 414 may move to the inner or outer space of the support 41 through the fixing hole.

Of course, when a plurality of the fixing member 412 is formed, the fixing hole is formed corresponding to the number of the fixing member 412, the position of the fixing hole is formed in various ways by the fixing member 412 In the support 41 is formed to be fixed.

An inner surface of the support 41 may be further provided with a stopper (not shown) for limiting the upward movement of the support 41 received in the inner space and withdrawn upward. The stopper is formed in a shape protruding toward the center from the inner surface of the support 41, the lower end of the support 41 to be drawn out by the stopper for limiting the upward extension of the support 41 by the stopper It may be formed more.

On the other hand, the case 43, which is supported upward by the support 41 is located at the upper end of the support (41). The case 43 is formed to have a predetermined internal space in a cylindrical shape having an upper surface and a lower surface open while having a predetermined diameter.

An elastic body 45 for supporting the support plate 44 upward by its elasticity is accommodated in the inner space of the case 43, and the lower side of the elastic body 45 restricts the downward movement of the elastic body 45. The limiting member 431 is positioned.

The elastic body 45 is positioned in the upper half of the inner space of the case 43 while having a certain degree of self-elasticity, and is formed in the form of a coil spring having elasticity in the vertical direction.

Of course, the elastic body 45 may be provided in various forms, not in the form of a coil spring. However, even if the elastic body 45 of any form is provided, it is preferable that the configuration is formed to support the support plate 44 upward by its own elasticity.

The limiting member 431 is formed in a disc shape having a predetermined thickness, a hole having a predetermined diameter is formed in the center portion thereof, and a lower end of the guide rod 46 penetrates through the hole. 431 is formed below.

The guide rod 46 positioned below the limiting member 431 is provided with a limiting fixing member 432 for limiting the downward movement of the limiting member 431. The restriction fixing member 432 is formed to protrude to both sides of the guide rod 46 in a state in which at least a portion of the guide rod 46 is fixed to the guide rod 46.

At least a portion of the limiting fixing member 432 is supported by the limiting member 431 by a portion protruding to both sides of the guide rod 46, thereby restricting the downward movement of the limiting member 431.

Since the downward movement of the limiting member 431 is limited by the limiting fixing member 432, the downward movement of the elastic body 45 is limited by the limiting member 431, so that the elastic body 45 may include the case ( 43) is placed in a state accommodated in the internal space.

On the other hand, the length of the restriction fixing member 432 protruding to the side of the guide rod 46 is formed shorter than the inner diameter of the support 41 which is introduced into the inner space of the case 43 is the support 41 The upper end of the) is configured to support the limiting member 431 from below.

That is, the support 41 is drawn upwards and the limit fixing member 432 is positioned in the inner space thereof, and the upper end of the support 41 passes through the limit fixing member 432 and the limit member 431. ) Can be supported from below.

An upper flange 433 is formed at an upper end of the case 43 to improve a contact area in contact with the bottom surface of the support plate 44. The upper flange 433 is formed to be bent sideways at the upper end of the case 43 to extend by a predetermined length.

The upper flange 433 is generally formed in a rectangular shape, and the upper surface of the upper flange 433 is in contact with the lower surface of the support plate 44 to support the support plate 44 from the lower side. The upper flange 433 is formed to have a predetermined thickness to ensure the support strength of the support plate 44.

Of course, the upper flange 433 may be fixed by welding or the like instead of being bent at the upper end of the case 43, or may be configured to be fastened by screws or bolts and nuts.

In addition, the upper flange 433 may be configured in the form of a disc rather than a rectangular shape as a whole, and may be configured to have a strength capable of supporting the support plate 44 in any form, even if configured in any form. Would be desirable.

The lower flange 434 is formed at the lower end of the case 43 to be in contact with the sensing unit of the displacement meter 42. The lower flange 434 is formed in a form in which an outer circumferential surface is bent outward so as to have a predetermined area at the lower end of the case 43.

The lower flange 434 is generally formed in the shape of a disc, and the lower portion of the flange 434 is in contact with the sensing portion of the displacement meter 42 to transmit the amount of change transmitted from the upper side to the sensing portion of the displacement gauge 42.

Of course, the lower flange 434 may be fixed by welding or the like instead of being bent outwardly from the lower end of the case 43, and may also be configured to be fastened with screws or bolts and nuts. will be.

In addition, the lower flange 434 may be configured to have a rectangular plate shape instead of a whole disc shape, and the lower flange 434 may be configured to be in contact with the sensing unit of the displacement meter 42 even if the bottom flange 434 is formed in any shape. will be.

The support plate 44 having a change amount corresponding to the displacement of the bridge 1 is positioned above the case 43 while being supported upward by the case 43. The support plate 44 is formed in the shape of a square plate having a predetermined thickness.

The upper surface of the support plate 44 is formed in a concave-convex shape in order to increase the contact frictional force by increasing the contact area of the portion in contact with the bridge (1). In other words, when the upper surface is formed in a planar shape, the contact frictional force is reduced. In order to prevent this, the upper surface of the support plate 44 is embossed or has a rectangular concave-convex shape having a predetermined area to increase the contact frictional force. .

The support plate 44 is formed of a material having almost no self-displacement, which is determined by the displacement amount of the bridge 1 when the support plate 44 behaves in the up-down direction according to the displacement occurring in the bridge 1. This is to have a corresponding amount of behavior.

In detail, when displacement occurs in the bridge 1, the displacement of the bridge 1 is transmitted to the support plate 44, and according to the displacement of the bridge 1 transmitted to the support plate 44. The support plate 44 behaves in a vertical direction, that is, in a displacement direction.

In this case, when the support plate 44 is formed of an elastic body having its own elasticity, the displacement generated in the bridge 1 is absorbed by the elasticity of the support plate 44, thereby accurately correcting the displacement of the bridge 1. Since it is impossible to measure, it is formed of a metal material having little self-displacement, for example, steel, and is configured to behave while having a corresponding amount of displacement according to the displacement occurring in the bridge 1.

A guide rod 46 for guiding the movement of the support plate 44 is mounted at the central portion of the support plate 44. The guide rod 46 is formed in the form of a rod having a small diameter in the vertical direction, the upper end is fixed to the central portion of the support plate 44, the lower end passes through the central portion of the elastic body 45 to the limiting member ( It is formed to penetrate the central portion of the 431.

The lower end of the guide rod 46 extends to the lower half of the inner space of the case 43 by passing through the center portion of the limiting member 431 while traversing the center portion of the case 43 in the vertical direction. At least a portion of the support 41 penetrating into the inner space of the support 41 is positioned in the inner space of the support 41.

The displacement meter 42 is mounted below the case 43. The displacement meter 42 is mounted to the support 41 so that the upper end portion is in contact with the lower surface of the lower flange 434 to be selectively removable.

The support 41 is provided with a mounting portion 421 for the selective fixing of the displacement meter 42. The mounting portion 421 is formed so that a portion is fixed to the support 41, while the other portion is formed to fix the displacement meter 42.

Hereinafter, the operation of the displacement measuring apparatus of the bridge according to the present invention configured as described above will be described.

The user fixes the fixing plate 411 to the bottom or ground surface of the water. In the state in which the fixing plate 411 is fixed, the height of the support 41 is adjusted to extend upward.

An upper surface of the support plate 44 is in contact with the upper structure of the bridge 1 by adjusting the length of the support 41 in the state where the case 43 is mounted on the upper end of the support 41.

When the support plate 44 is positioned in contact with the upper structure of the bridge (1), the user adjusts the length of the support (41) so that the measuring device 40 and the upper structure of the bridge (1) It is installed to be fixed between the ground or the bottom of the water.

At this time, the support plate 44 is supported by the case 43 from below, and is supported in the inner space of the case 43 by the upper end of the support 41 which is penetrated through the lower surface of the case 43. As the limiting member 431 positioned upward is supported upward, the elastic member 45 positioned in the inner space of the case 43 is compressed upward.

On the other hand, the lower side of the case 43 is mounted so that the sensing unit of the displacement meter 42 is in contact with the lower flange 434. The displacement meter 42 is connected to the control unit so that the user can collect the data is configured to transmit the data.

As such, when the measuring device 40 of the bridge supported by the support 41 while the support plate 44 is in contact with the upper structure of the bridge 1 is installed, the displacement generated in the bridge (1) By detecting by the displacement meter 42 and transmitting to the control unit, the user can measure the displacement generated in the bridge (1) to be data.

When displacement occurs in the bridge 1, the displacement of the bridge 1 is transferred to the support plate 44 so that the support plate 44 moves downward by the amount of change generated.

As the support plate 44 moves downward by the displacement occurring in the bridge 1, the case 43 positioned below the support plate 44 moves downward by the same amount of movement as the support plate 44. do.

When the case 43 moves downward, the lower flange 434 positioned at the lower end of the case 43 moves downward. The lower flange 434 is transferred to the sensing unit of the displacement meter 42 positioned below the lower flange 434.

The amount of movement of the support plate 44 transferred to the sensing unit of the displacement meter 42 may be data at the control unit connected to the displacement meter 42 to perform a load test for diagnosing the safety of the bridge 1.

The description of the present invention as described above is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains various modifications without departing from the essential characteristics of the present invention. Modifications may be possible.

For example, in the above-described embodiment, an embodiment of measuring displacement of a bridge is disclosed, but an embodiment of measuring inter-layer displacement of a building structure, not displacement of a bridge, may be possible.

The displacement measuring apparatus of the bridge according to the present invention is configured to be supported upward so that the vertical displacement can be measured during the load test for evaluating the load capacity of the bridge.

Accordingly, it is easy to install and have a merit of measuring the displacement due to the dynamic load of the bridge superstructure in the case of a river or a shallow surface of the shallow depth, so that the displacement of the bridge can be easily measured during the load test.

Due to these various advantages and effects, the apparatus for measuring displacement of a bridge according to the present invention will have great applicability for improving the safety of not only bridge construction industry but also various industries and bridges related thereto.

1. Bridge 2. Superstructure
3. Infrastructure 21. Slab
22. Girder 31. Pier Coping Department
32. Pier Column 33. Foundation
40. Measuring device 41. Support
411. Fastening plate 412. Fastening member
413. Fixed part 414. Athletic part
42. Displacement meter 421. Mounting part
43. Case 431. Restriction member
432. Restriction member 433. Upper flange
434. Lower flange 44. Support plate
45. Elastomers

Claims (6)

The lower end is supported on the ground, the support can be adjusted in height upward;
A displacement meter mounted to the support;
A case positioned above the displacement gauge and supported by the support;
A support plate supported on the case at an upper side of the case and having a moving range corresponding to displacement of the superstructure directly supporting the upper load of the structure;
An elastic body for supporting the support plate upward by its elasticity; And
A guide rod having an upper end fixed to the support plate to guide the movement of the support plate; Displacement measuring device configured to include. The method of claim 1,
Displacement measuring device is provided on the support is detachably fixed for selectively mounting the displacement meter. The method of claim 1,
Displacement measuring device having an upper surface of the support plate has an uneven shape. The method of claim 1,
The support plate is a displacement measuring device is formed of a metal material with a small amount of displacement. The method of claim 1,
In the case,
And a lower flange formed to contact the upper end of the displacement meter, and an upper flange formed to contact the lower surface of the support plate. The method of claim 1,
Displacement measuring device is provided in the inner space of the case is supported by the support from below while limiting the downward movement while supporting the elastic body from below.

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