KR101991336B1 - Total Deformation Measuring Instrument of Pot Bearing and Measuring Method Thereof - Google Patents

Abstract

The present invention relates to an instrument for measuring a movement amount of a pot bearing and a measuring method thereof, in a bridge adopting a pot bearing as a bridge bearing type, more conveniently and accurately measuring the relative displacement between an upper plate and a lower plate of a bearing device using a scale plate and a laser pointer. The instrument includes a pair of expansion rods (10, 20) being left and right symmetric; and a guide member (40) accepting the expansion rods (10, 20). The expansion rods (10, 20) are formed of a rectangular box with an elastic body (30) therein with clamps (12, 22) elastically fixated at a side surface (203) of the upper plate (202) and a side surface (205) of a lower plate (204) at one side thereof. The guide member (40) is provided with, in a longitudinal direction, guide surfaces (42, 44), insertion grooves (16, 26), the scale plate (48) where a zero point is marked at the center of a bottom surface or an upper surface to show a scale with the unit of mm left and right, the laser pointer (50) radiating laser, and an operating switch (52) for operating the laser pointer to be fitted into a guidepost (46) and to be able to slide.

Description

TECHNICAL FIELD [0001] The present invention relates to a pot measuring apparatus,

More particularly, the present invention relates to a device for measuring the amount of movement of a port and a method for measuring the amount of movement of the port, And a measurement method using the same. 2. Description of the Related Art [0002] The present invention relates to a device for measuring a relative displacement of a top plate and a bottom plate,

Fig. 1 and Fig. 2 are views showing the structure of a general bridge. Fig. 1 is a photograph showing a general bridge 100 and a bridge support, and Fig. 2 is a side view explaining the function of the bridge support. Referring to these drawings, a general bridge 100 includes an upper structure as an upper plate 102 directly supporting a load of a vehicle or the like, a plurality of abutments 104 supporting the upper plate 102, Pier). These multiple alternations 104 and piers 106 are referred to as substructures. Between the upper structure and the lower structure, a bridge support 120 capable of transmitting a load acting on the upper structure downward is installed.

In case of a steel bridge (steel bridge) installed in a cold region, the bridge overhead structure is elongated and contracted according to seasonal temperature change, that is, -20 ° C in winter and + 40 ° C in summer, A resistance force or a resistance force is generated in the upper structure due to the displacement constraint, so that one fixed point 122 is provided as the movable point and the other point is provided as the movable point 124, So that stress (resistance) is not generated.

2, a horizontal displacement occurs in proportion to an expansion length at a fixing point (a fixed point bridge support mounting point), and in addition to the temperature change, The horizontal displacement occurs in the bridge support 120 even if the displacement of the lower structure such as the lateral flow of the bridge support 120 occurs. For example, according to the seasonal temperature change, the expansion of the bridge girder installed in alternation 2 is calculated as ΔL = α · ΔT · L, where α is the thermal expansion coefficient, 1.2x10 ^-5 for the steel bridge, ΔT is the temperature variation, L is the elongation field (the distance from the fixed point to the measurement point). In the case of the expansion joint of 190.0m, the horizontal displacement of ΔL = 1.2x10 ^-5 · 60 ℃ · 190,000 ㎜ = 136.8 ㎜ is caused by the elongation in the winter and the lower structure is fixed to the support layer, It appears as a deformation of the base.

The plurality of bridge supports 120 are members having an allowable horizontal displacement of an appropriate amount according to the product standard (support size, allowable load, etc.), and only the bridge support 120 can not perform its function, In case of a large amount of deformation due to the occurrence of under-floor displacement such as errors in installation and lateral flow, horizontal force acts on the substructure due to damage of rubber plate, fluorine resin plate and friction coefficient inside the base, Damage and destruction of the support part may also occur. It is obvious that large-scale safety accidents are inevitably expected when they are neglected. In FIG. 2, reference numeral 107 denotes a bridge coping.

Therefore, the measurement of the movement of the bridge pedestal 120 and the analysis of the behavior by the temperature change in the bridge inspection are very important measurement items, and the precise inspection and the precise safety diagnosis are performed for all the points. In order to guarantee the safety of the public, the government has enacted the "Special Act on the Safety and Maintenance of Facilities", and in the sub-law stipulating the specific contents, the "Safety Inspection and Safety Inspection And detailed guidance for precise safety diagnosis (December 2016) ", it is stipulated that it should be investigated for the state of expansion and contraction of the bridge support 120, breakage of the fixing device and relaxation.

3 is a partially cutaway perspective view showing a port support 200 in a general bridge support, and is an example of a port support in a bridge support. The port support 200 is constituted by a lower plate 204 which is a steel plate fixed to an upper plate 202 and a bridge 104 or pier 106 that are a lower plate and a lower plate, respectively, . A sliding plate 206 is fixed to the upper plate 202 between the upper plate 202 and the lower plate 204 and a rubber plate 212 which transmits a vertical force is installed in the lower plate 204, A piston 208 for preventing any deviation of the rubber plate 212 is provided on the base plate 212. [ A fluororesin plate 210 is installed between the sliding plate 206 and the piston 208 to minimize frictional force. The reference numeral 214 is a socket fixed on the superstructure or the substructure.

In the movable support, the horizontal displacement from the upper structure is transmitted to the lower structure while the relative displacement between the upper plate 202 and the lower plate 204 due to the sliding function between the sliding plate 206 and the fluorine resin plate 210 And the like. In some products of the port support 200, a scale or an indicator may be provided on the top plate 202 and the bottom plate 204 for measuring the amount of movement of the support. However, due to the breakage of the indicator, Frequent cases of loss of utility occur.

4A to 4D are explanatory diagrams showing an example of a conventional method of measuring a port-transfer amount. FIG. 4A is a photograph showing a state in which the movement of the port support is measured using a tape measure in a state in which a ruler is not installed, FIG. 4C is a photograph showing a state in which a ruler is provided on the upper and lower plates, And 4d is a photograph showing the state of measurement of the port support movement amount by using a ruler and an indicator.

As described above, the conventional port support moving amount measurement is performed by wiping the side surface of the port base with a clean cloth, drawing a line 260 perpendicularly to the center of the top plate 202 and the center of the bottom plate 204, The difference in the movement amount between the plate 202 and the lower plate 204 is discriminated. Such a primitive conventional method of measuring a port-based moving distance is a method of visually analyzing and drawing a line in a narrow space, so that the measurement is difficult and complicated, and a measurement error frequently occurs. In these figures, numeral 250 is a ruler, 252 is a ruler, and 254 is an indicator.

As described above, there is a problem in that the measurement of the port-bearing movement amount in the related art is ineffective in spite of the presence or absence of the scale or indicator, and the side surface of the port is wiped with a cloth, In addition, by drawing a line 260 perpendicular to the movement restricting device, it is possible to determine the difference in the amount of movement of these parts, so that a judgment is made visually in a narrow space and a line is drawn. There is a problem that arises.

Therefore, it was a long-standing necessity of the industry to solve the problem of the individual difference in the measurement technique of the measuring person and the artificial measurement error in the measurement of the movement amount of the port support of the elastic support type of the bridge. In order to solve the above-described problems, the present invention provides a port-bearing deformation-measuring device for vertically mounting a laser pointer on a deformation-measuring member to more accurately measure deformation amounts (deformation amounts of the upper and lower ends) The purpose is to provide.

In order to achieve the above object, there is provided a port support moving amount measuring device of a bridging elastic support type, comprising a port support having at least a sliding plate fixed to an upper plate and a rubber plate having a vertical force transmitting a vertical force,

A pair of right and left symmetrical extension rods,

These expansion rods are formed of a rectangular enclosure having an elastic body therein and have a clamp which is elastically fixed to the side surface of the upper plate and the side surface of the lower plate at one side of the expansion rod,

A guide member for receiving the extension rod,

The guide member has a guide surface and a fitting groove along the longitudinal direction so as to be engaged with the guide post so as to be able to slide, and a scale plate on which a zero point is marked at the center in the bottom or upper surface, , A laser pointer for irradiating a laser, and an operation switch for operating the laser pointer,

The elastic body is fixed to one side of the clamp of the extension rod and the other side of the elastic body is fixed to the fixing points of both side surfaces of the guide member and elastically installed on the upper plate and the lower plate to measure the amount of deformation of the elastic support.

In addition, it is preferable that the extension rods are installed within 200 mm from the left and right ends of the guide member.

Further, in the method of measuring the amount of movement of the port-

A method of measuring a relative displacement difference between an upper plate and a lower structure coupled to an upper structure or a lower plate coupled to a bridge, the movement amount of the bridge support being a method of measuring a deformation amount of a bridge in which a bridge support type is an elastic support,

Setting a zero point on the center of the guide member and a laser pointer marked with a scale in mm on the left and right and a laser pointer on the lower portion of the upper plate and the upper portion of the lower plate, Irradiating a laser beam of the laser pointer to a scale plate of a guide member and a scale plate of a lower plate; Reading a distance L between a point of the laser pointer irradiated on the scale plate of the upper plate side guide member and a point of the laser pointer irradiated on the scale plate of the lower plate side guide member; Determining a distance that the guide member of the upper plate moves from a zero point of the guide member of the lower plate as a deformation amount; .

As described above, the portage moving amount measuring device and the measuring method using the same according to the present invention have the following effects.

1. In the precise inspection and precise safety diagnosis of a bridge with a bridge-type bridge support, there is a problem in that the measurement of the conventional port-bridge movement amount is inferior in measurement efficiency despite the presence or absence of the scale or indicator. However, Since the vertical precision is increased by the installed laser pointer, the deformation amount of the bridge support can be accurately measured.

2. Conventionally, the side of the port base is wiped with a cloth, and a line is drawn perpendicularly to the center of the upper plate and the lower plate by a stationary pen to determine the difference in the amount of movement of these parts. The problem of measurement error which is very difficult and complicated and frequent measurement error is solved, that is, the problem of individual difference of an individual measurement technique or an artificial measurement error is fundamentally resolved by beam irradiation of a laser pointer It provides a scientific measurement method, so it can accurately analyze the behavior of the bridge and evaluate the condition of the bridge. Moreover, it is easy to carry and measure the product, so that the technical measurement error of each individual is small and can be easily used by anyone.

3. Although there are many existing portage transfer distance measuring devices, it is a primitive type and complicated device, so it has a low practical application rate. However, it is easy to carry and easy to use, so it can measure the deformation amount easily and easily on site.

1 is a photograph showing a general bridge and a bridge support,
2 is a side view illustrating the function of the bridge support,
3 is a partially cutaway perspective view showing a general resilient support type bridge support,
FIGS. 4A to 4D are explanatory views showing an example of the elastic bearing moving amount measurement according to the related art,
5 is an exploded perspective view showing a main body of a measuring instrument according to the present invention,
6 is an enlarged sectional view taken along the line A-A 'in Fig. 5,
7 is an enlarged perspective view of the laser pointer portion of the present invention,
8 is a perspective view for explaining a measuring method of the measuring instrument of the present invention,
Fig. 9 is a flowchart showing a procedure of a measuring method according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. FIG. 5 is an exploded perspective view showing a main body of the measuring instrument according to the present invention, and FIG. 6 is an enlarged sectional view taken along line A-A 'of FIG.

In these drawings, reference numerals 10 and 20 designate a pair of left and right symmetrical extension rods. The main body of each of the extension rods 10 and 20 is formed of a rectangular enclosure having an elastic body 30 therein and has a rubber plate 14 and 24 on one side of the extension rods 10 and 20, 12, and 22 are attached at right angles. The upper and lower surfaces of the extension rods 10 and 20 are fitted with the guide posts 46 of the guide member 40 to be described later and are formed in the longitudinal direction along the longitudinal direction so that the slide grooves 16 and 26 are formed . The extension rods 10 and 20 and the guide member 40 are fitted to each other so that they are fitted to each other at a lower portion of the upper plate 202 and at an upper portion of the lower plate 204 respectively.

In FIG. 6, reference numeral 40 denotes a guide member for receiving the extension rods 10, 20. The guide member 40 also has a rectangular shape for accommodating and receiving the rectangular expanding rods 10 and 20 and has guide surfaces 42 and 44 on upper and lower sides, respectively.

7 is an enlarged perspective view of the laser pointer portion of the present invention. A laser pointer 50 for irradiating a laser beam is formed at the center of the guide member 40. The laser pointer 50 is provided at the center of the guide member 40, An operation switch 52 is provided. It is preferable that the extension rods 10 and 20 are installed within the guide member 40 in a range of 200 mm from the left and right ends of the guide member 40. [ The guide members 40 are provided with extension rods 10 and 20 at the left and right ends of the guide member 40. When the extension rods 10 and 20 are loosened and expanded, Guide function. The elastic members 30 and the extension rods 10 and 20 having the springs are freely slidable in and out by the guides of the guide surfaces 42 and 44 formed in the guide member 40. That is, since the clamps 12 and 22 mounted on both ends of the extension rods 10 and 20 are always pulled inward by the elastic body 30, 203 and the upper surface of the lower plate 204 by clamps 12, 22 which are in close contact with the side surface 205 of the lower plate 204. [

In this way, the displacement amount of the port-bearing moving amount measuring apparatus of the present invention is measured by the following procedure. First, the measuring instrument of the present invention includes clamps 12 and 22 attached to both sides of the extension rods 10 and 20 on the lower portion of the port support upper plate 202 and the lower plate 204 of a conventional bridge. And the other end is resiliently fixed to both side surfaces 32 of the guide member 40. The guide member 40 is fixed to the guide member 40 by elasticity. 5, one end of the elastic body 30 is fixed to the clamps 12 and 22 and the other end is fixed to both sides 32 of the guide member 40, And fixed to the point 34 elastically. At this time, the position of the laser pointer 50 is set at the center of the upper plate 202 and the lower plate 204.

FIG. 8 is a perspective view for explaining a measuring method of the measuring instrument of the present invention, and FIG. 9 is a flowchart showing a measuring method procedure according to the present invention. In this way, the displacement amount of the port-bearing moving amount measuring apparatus of the present invention is measured by the following procedure. First, the measuring instrument of the present invention includes clamps 12 and 22 attached to both sides of the extension rods 10 and 20 on the lower portion of the port support upper plate 202 and the lower plate 204 of a conventional bridge. And the other end is resiliently fixed to both side surfaces 32 of the guide member 40. The guide member 40 is fixed to the guide member 40 by elasticity. 5, one end of the elastic body 30 is fixed to the clamps 12 and 22 and the other end thereof is fixed to both sides 32 of the guide member 40, as shown in FIG. And fixed to the fixing point 34 elastically. At this time, the position of the laser pointer 50 indicates a zero point (zero point) at the center of the top plate 202 and the bottom plate 204.

The method of measuring the amount of displacement in a bridge in which the bridge support type is an elastic support is described in more detail step by step. The bridge plate 204 is connected to the upper structure 202, which is the amount of movement of the bridge support, A scale plate 48 is mounted on the lower part of the upper plate 202 and on the upper part of the lower plate 204 and is provided with the guide member 40, And the laser pointer 50 are set to zero at the center of the guide member 40 (S100).

The operation switch 52 of the laser pointer 50 is operated to move the laser beam 50 of the laser pointer 50 to the scale plate 48 of the guide member 40 of the upper plate 202 and the scale plate 48 of the lower plate 204 (S110). At this time, a laser spot 54 appears on each of the scale plates 48 as shown in FIG.

The laser pointer irradiated on the scale plate 48 of the guide member 40 on the upper plate 202 side and the laser pointer irradiated on the scale plate 48 of the guide member 40 on the lower plate 204 side, The moving distance L to the base point 54 is read (S120).

Next, the distance that the guide member 40 of the upper plate 202 moves from the zero point of the guide member 40 of the lower plate 204 is determined as the deformation amount (S130).

As described above, according to the present invention, after the guide member 40 is fixedly attached to the support device upper plate 202 and the lower plate 204, the beam of the laser pointer 50 is irradiated to the relative scale plate 48, This value is the amount of movement of the base unit when the scale is moved.

10, 20: extension rod 12, 22: clamp
16, 26: fitting groove 30: elastic body
32: Both sides 34: Fixed point
40: guide member 42, 44: guide surface
46: guide post 48:
50: laser pointer 52: operation switch
54: Base point (point of view) 202: Top plate
204:

Claims (3)

A port support movement type port support (200) including a port support (200) having a sliding plate (206) fixed to at least an upper plate (202) and a rubber plate (212) In the measuring device,
A pair of right and left symmetrical extension rods 10 and 20,
The side walls 203 and the bottom plate 204 of the upper plate 202 are formed at one side of the extension rods 10 and 20, (22) elastically fixed to a side surface (205)
A guide member 40 for receiving the extension rods 10 and 20,
The guide member 40 has guide surfaces 42 and 44 and fitting grooves 16 and 26 along the longitudinal direction so as to be engaged with the guide posts 46 so as to be able to slide, A scale plate 48 in which a zero point is marked at the center and in which a ruler in mm units is displayed on the left and right sides, a laser pointer 50 for irradiating a laser beam, and an operation switch 52 for operating the laser pointer 50,
One side of the elastic body 30 is fixed to the clamps 12 and 22 of the extension rods 10 and 20 and the other side thereof is fixed to the fixing points 34 of both side surfaces 32 of the guide member 40, And the deformation amount of the elastic support is measured by being elastically installed on the plate (202) and the lower plate (204).
2. The port support movement amount measuring apparatus according to claim 1, wherein the extension rods (10) and (20) are installed within a distance of 200 mm from left and right ends of the guide member (40). delete

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