KR20230012268A - Longitudinal Displacement Measurement Device for Bridge Upper Structure - Google Patents

Abstract

Disclosed is a longitudinal displacement measurement device for a bridge superstructure which can quickly and accurately measure the longitudinal (axial direction of a bridge) displacement of a girder relative to an abutment. According to the present invention, the longitudinal displacement measurement device for a bridge superstructure comprises: a displacement measurement ruler installed on the upper surface of an abutment and having measurement gradations on the front surface thereof; a transfer bar connection pin slidably coupled to a slide groove formed on one surface of the displacement measurement ruler in a first direction parallel with a longitudinal direction; a lateral displacement transfer bar arranged in a second direction perpendicular to the first direction, wherein one end thereof is fixed on a girder and the other end thereof on the opposite side is connected to the transfer bar connection pin; a first measurement needle slidably coupled to the slide groove on one side of the lateral displacement transfer bar; and a second measurement needle slidably coupled to the slide groove on the other side of the lateral displacement transfer bar.

Description

Longitudinal Displacement Measurement Device for Bridge Upper Structure}

The present invention relates to an apparatus for measuring displacement in the direction of a bridge superstructure, and more particularly, to an abutment (a structure installed at both ends of a bridge to transmit a load of a bridge superstructure to the ground below and simultaneously receiving earth pressure acting on the rear surface) It relates to a bridge superstructure displacement measuring device for measuring the displacement of a girder (bridge superstructure) in the axial direction (axial direction of the bridge).

The bridge is structurally composed of a bridge superstructure (slabs and girders) on which vehicles or people move on the upper part, and a shift or pier to support these bridge girders on the lower part. In addition, a support is provided between the abutment or pier and the bridge girder to support the fixed load and moving load of the bridge superstructure (slab and girder), while changing temperature or displacement due to impact such as wind and seismic force. Accommodates displacement in the throttle direction.

As mentioned above, bridges undergo expansion and contraction displacement according to temperature changes. In addition, many bridge structures undergo external deformation according to their durability and deterioration, and earthquakes and typhoons aggravate the deformation of old facilities. Irregular and minute gradual deformation of the exterior deteriorates the performance of the bridge and the safety of the bridge structure, so continuous management and inspection are required.

One of the bridge management inspection elements is the measurement of the expansion displacement according to the temperature change of the girder, which is the upper structure of the bridge, and in the prior art, the operator directly approaches the top of the abutment and measures it with a tape measure. This method has the advantage of being able to measure quickly at low cost, but has the disadvantage of low measurement precision and low safety and convenience in view of the working environment.

Accordingly, a technology for safely and accurately measuring the displacement of the girder in the direction of the bridge has been proposed through Korean Patent Registration No. 10-1522193 under the name of 'displacement measuring device for superstructures of bridges'. It is installed across the girder and the abutment and pier supporting it, and consists of two or more displacement measuring units with measurement scales, a frame for width adjustment, a frame for installing a displacement meter, and a hanger.

Since the conventional bridge upper structure displacement measuring device having such a configuration is a method of measuring by installing a displacement measurer at each measurement point along the vertical frame for installing the displacement meter, the displacement of the elastic support and the girder as well as the displacement of the additional slab can be measured simultaneously. However, the configuration is quite complicated, and a lot of time and manpower are required for field application as much as the complex configuration.

Korean Patent Registration No. 10-1522193 (registration date 2015.05.15.)_Displacement measuring device for upper structure of bridge

The technical problem to be solved by the present invention is a girder for a shift (bridge, a structure installed at both ends of the bridge to transmit the load of the bridge superstructure to the ground below and simultaneously receiving the earth pressure acting on the back side) according to temperature change It is an object of the present invention to provide a bridge superstructure displacement measuring device capable of quickly and accurately measuring the extension displacement in the bridge axis direction (bridge axial direction) of (bridge superstructure).

Another technical problem to be solved by the present invention is to provide a bridge superstructure bridge direction displacement measuring device that is simple enough to be easily applied to existing bridge structures without special structural changes and can minimize cost as the configuration is simple. is to do

According to an embodiment of the present invention as a means of solving the problem,

As a device for measuring the displacement in the bridge axis direction (axial direction of the bridge) of the girder installed on the abutment,

a displacement measuring device installed on the upper surface of the abutment and having a measurement scale on the front side;

a transmission rod connection pin slidably coupled to a slide groove formed on one surface of the displacement measurer in a first direction parallel to the axial direction;

a transverse displacement transmission rod disposed in a second direction perpendicular to the first direction, one end fixed to the girder and the other end connected to the transmission rod connection pin;

a first measurement needle slidably coupled to the slide groove at one side of the transverse displacement transmission rod; and

Provides a bridge superstructure bridge axial direction displacement measuring device including a second measurement needle slidably coupled to the slide groove on the other side of the transverse displacement transmitting rod.

Here, in an initial setting state of the device, at least a part of the first measuring needle and the second measuring needle may be disposed to be in contact with one side of the transfer rod connecting pin and the other side of the opposite part.

Preferably, when the girder contraction displacement is pushed by the transmission rod connecting pin to which the transverse displacement transmission rod is connected, the first measurement needle is moved in the direction in which the contraction displacement occurs by the amount of displacement of the girder, and the transmission rod to which the transverse displacement transmission rod is connected during girder extension displacement Pushed by the connection pin, the second measurement needle may be configured to move in the direction in which the extension displacement occurs by the amount of displacement of the girder.

Here, the first measurement needle is configured so that the measurement tip faces upward in front of the displacement measurer, and the second measurement needle has the measurement tip opposite to the first measurement needle pointing downward in the front face of the displacement measurer. It can be configured to face.

Preferably, a contraction displacement measurement scale is formed in a first direction on the upper front area of the displacement measurer based on the slide groove formed in the first direction, and an extension displacement measurement scale is formed in the first direction on the lower front area of the displacement measurer. can be formed.

Here, a colored coating layer or color sheet may be attached to the surfaces of the first measurement needle and the second measurement needle, and at this time, a color coating layer or color sheet on the surface of the first measurement needle and the second measurement needle. The color of can be formed differently.

In addition, a first communication module having a limit switch is installed at a location away from the initial position of the transmission rod connection pin in the direction of contraction of the girder (the point where the contraction margin is insufficient) in the upper front area of the displacement measuring device based on the slide groove. And, based on the slide groove, a second communication module having another limit switch at a location away from the initial position of the transmission rod connecting pin in the direction in which the girder extends (the point where the extension margin is insufficient) is located in the lower front area of the displacement measuring device based on the slide groove. can be installed

According to the bridge superstructure displacement measuring device according to an embodiment of the present invention, as an alternating attachment method, a worker visually (in some cases, using a telescope) in a safe position without direct access can measure the stretching displacement of the girder in the bridge direction according to the temperature change. can be safely, easily and accurately measured, and has the advantage of being easily applicable to existing bridge structures without special structural changes due to its simple configuration.

1 is an exploded perspective view of an apparatus for measuring displacement in the bridge axis direction of a bridge superstructure according to an embodiment of the present invention.
2 is a combined perspective view of a bridge superstructure displacement measuring device in the bridge axis direction according to an embodiment of the present invention.
Figure 3 is a front view of the bridge superstructure displacement measuring device shown in Figure 2 in the bridge shaft direction.
4 is a cut-away perspective view of an apparatus for measuring displacement in a direction of a bridge superstructure according to an embodiment of the present invention, viewed from a position of a transverse displacement transmitting rod;
5 is an exemplary installation view illustrating a state in which a displacement measuring device in a direction of a bridge superstructure according to an embodiment of the present invention is installed on a bridge;
6 and 7 are diagrams illustrating an operating state of the device for measuring displacement in the bridge shaft direction of a bridge superstructure according to an embodiment of the present invention.

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

In describing the present invention, terms used in the following specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise.

In addition, the terms "include" or "having" in this specification are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other It should be understood that the presence or addition of features, numbers, steps, operations, components, parts, or combinations thereof is not precluded.

Also, terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another.

In addition, terms such as "...unit", "...unit", and "...module" described in the specification mean a unit that processes at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software. can

In the description with reference to the accompanying drawings, the same reference numerals will be given to the same components, and overlapping descriptions thereof will be omitted. In addition, in the description of the present invention, if it is determined that a detailed description of a related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted.

1 is an exploded perspective view of a bridge superstructure displacement measuring device according to an embodiment of the present invention, and FIG. 2 is a combined perspective view. 3 is a front view of the bridge superstructure displacement measuring device shown in FIG. 2, FIG. 4 is a cutaway perspective view of the present invention, and FIG. 5 is a view illustrating how the present invention is installed on a bridge.

1 to 5, the device 1 for measuring displacement in the axial direction of the upper structure of a bridge according to an embodiment of the present invention is the displacement of the girder 3 located at the top of the abutment 2 in the axial direction (axial direction of the bridge) As a device for measuring, it includes a displacement measuring device 10 installed on the upper surface of the abutment 2. The displacement measurer 10 may be a rectangular plate-shaped body elongated in a first direction parallel to the axial direction, and has a slide groove 103 extending in the first direction along a central surface.

Measurement scales 102 and 104 are formed on the front surface of the displacement measuring device 10 having the slide groove 103 continuous in the first direction. The measurement scales include the contraction displacement measurement scales 102 formed at equal intervals in the first direction on the upper front area of the displacement measuring element 10 based on the slide groove 103, and the lower front area of the displacement measuring element 10. It can be divided into extension displacement measuring scales 104 formed at equal intervals in the first direction.

The slide groove 103 may be formed in a cross-sectional shape with a wider bottom surface in the depth direction than the inlet, for example, a dovetail shape, and the transfer rod connecting pin 12 and the first measurement The needle 16 and the second measuring needle 17 are slidably coupled. At this time, each of the transfer rod connecting pin 12 and the first and second measurement needles 16 and 17 may have binding members 120, 160 and 170 sliding in a state engaged with the slide groove 103 on their rear surfaces. can

The transmission rod connecting pin 12 slidably coupled to the slide groove 103 has a connecting ring 122, and one end (lower end) of the transverse displacement transmission rod 14 is attached to the connecting ring 122. It is connected in an interlocking fashion. At this time, the transverse displacement transmission rod 14 may have a long rod-shaped structure in the second direction perpendicular to the first direction, and the other end (upper end) of the transverse displacement transmission rod 14 opposite the portion connected to the transmission rod connecting pin 12 ) can be fixed to the girder (3).

The lateral displacement transmission rod 14 may be fixed to the girder 3 by means of anchor bolts or by making a hole on the side of the girder 3 and fixing there by a forced fitting method. At one side of the lateral displacement transmission rod 14, the first The measurement needle 16 is slidably coupled to the slide groove 103, and the second measurement needle 17 can be slidably coupled to the slide groove 103 on the other side of the lateral displacement transmitting rod 14. .

As shown in FIG. 5, when the two measuring needles 16 and 17 are disposed oppositely with the transverse displacement transmission rod 14 interposed therebetween, the transmission rod connecting pin 12 with the transmission rod connecting pin 12 interposed therebetween ) (or transverse displacement transmission rod 14) and at least a part of the first measurement needle 16 and the second measurement needle 17 are brought into contact with the other side of the opposite part, thereby transmitting transverse displacement during expansion and contraction of the girder (3) In conjunction with the movement of the rod 14, one of the two measuring needles 16 and 17 may be configured to move together.

According to this configuration, the first measuring needle 16 in contact with one side of the transmission rod connecting pin 12 is pushed by the transmission rod connecting pin 12 when the girder 3 shrinks and displaces, and the amount of displacement of the girder 3 increases. The second measurement needle 17, which is moved in the direction in which the contraction displacement occurs and is in contact with the other side of the transmission rod connecting pin 12, is pushed by the transmission rod connecting pin 12 when the girder 3 is elongated, and the amount of displacement of the girder 3 It can be moved in the direction in which the extensional displacement occurs as much as possible.

The first measurement needle 16 preferably has a measurement tip 162 formed in a first direction on the upper front surface of the displacement measurer 10, more specifically, a contraction displacement measurement scale 102. It may be configured to face, and the measurement tip 172 of the second measurement needle 17 is a measurement scale formed in the first direction on the lower front side of the displacement measurer 10, opposite to the first measurement needle 16, More specifically, it may be configured to face the extension displacement measuring scale 104.

The surfaces of the first measuring needles 16 and the second measuring needles 17 are painted with a colored paint layer so that workers can easily identify the measuring needles even from a certain distance away when measuring the stretching displacement of the girder (3). or a colored color sheet may be attached, and at this time, if the color of the color coating layer or color sheet on the surface of the first measurement needle 16 and the second measurement needle 17 is different, the displacement generated in the girder 3 is elongated or not. You can tell right away whether it's a contraction or not.

Hereinafter, a process of measuring the displacement of a bridge superstructure, that is, a girder, using the displacement measuring device after installation and installation of the displacement measuring device in the direction of the bridge superstructure according to an embodiment of the present invention will be briefly reviewed.

Referring back to FIG. 5, first, in installing the device, the displacement measuring device 10 is fixed to the upper surface of the abutment 2. More specifically, the displacement measurer 10 is installed on the upper surface of the abutment 2 so that the front surface of the displacement measurer 10 having the measurement scale is exposed to the outside when viewing the bridge structure from the side. At this time, by using an anchor bolt or the like, the displacement measuring device 10 can be firmly attached and fixed to the upper surface of the abutment 2.

Next, one end (upper end) of the transverse displacement transmission rod 14 is fixed to the lower surface of the girder 3, and the other end (lower end) is slidably coupled to the slide groove 103 of the displacement measurer 10 Transmission It connects with the rod connecting pin (12). In fixing the transverse displacement transmission rod 14 to the girder 3, it is fixed to the designated position of the girder 3 by an anchor bolt method, or by making a hole on the girder 3 side and fixing it there by a forced fit method. can

When the connection of the lateral displacement transmission rod 14 is completed, the first measurement needle 16 and the second measurement needle 17 are connected to one side of the transmission rod connection pin 12 (or the lateral displacement transmission rod 14) and the other side of the opposite part By directly adjusting the initial position of the measurement needles so that the girder (3) is stretched and retracted, the device setting is easy and can be completed quickly.

In the bridge superstructure bridge axial displacement measuring device according to the embodiment of the present invention installed as described above, one side of the transmission rod connecting pin 12 (or the transverse displacement transmission rod 14) and the transmission rod connecting pin 12 are interposed therebetween. Since at least a part of the first measuring needle 16 and the second measuring needle 17 are in contact with the other side of the opposing part, the two measuring needles 16, 17) will move together.

For example, as shown in FIG. 6 showing the operating state of the present invention during contraction displacement of the girder 3, when contraction displacement occurs in the girder 3 in the direction of the bridge axis with respect to the abutment 2 supporting the girder 3 , The transverse displacement transmission rod 14, one end of which is fixed to the girder 3, also moves in the direction in which the contraction displacement occurs, and the first measurement needle 16 is pushed by the transverse displacement transmission rod 14 to As much as the displacement amount, it moves in the direction in which the contraction displacement occurred.

In contrast to the elongation of the girder 3, as shown in FIG. 7 showing another operating state of the present invention, the second measuring needle ( 17) moves as much as the displacement of the girder 3 in the direction in which the extension displacement occurs, and the operator can measure the displacement amount ( length) can be determined quickly and accurately.

The conventional measurement method in which a worker directly approaches the top of the shift and measures with a tape measure has the advantage of being inexpensive and quick measurement. However, there is a disadvantage in that the bridge displacement management is not systematically and efficiently due to the low measurement precision, and in addition, there is a disadvantage in that it is dangerous and inconvenient because the operator has to directly access the top of the abutment.

On the other hand, the bridge superstructure displacement measuring device according to an embodiment of the present invention is an alternating attachment method, and the operator visually (using a telescope in some cases) in a safe position without direct access to expand and contract the girder in the bridge direction according to the temperature change. Displacement can be measured safely, easily and accurately, and the configuration is simple, so it can be easily applied to existing bridge structures without special structural changes.

Meanwhile, FIG. 8 is a front view showing another preferred embodiment of the bridge superstructure displacement measuring device according to the present invention.

As shown in another embodiment of FIG. 8 , the bridge superstructure displacement measuring device 1' according to the present invention may further include communication modules 18 and 19 having limit switches 180 and 190. . Here, the limit switches 180 and 190 are formed to a length that can overlap at least a part of the measuring needle when viewed from the first direction, so that the switch turns by being pressed by the measuring needles 16 and 17 that are moved according to the stretching displacement of the girder 3 It may be configured to be turned on.

The communication modules 18 and 19 may have a built-in configuration with a communication antenna (not shown) to wirelessly transmit information to an external bridge monitoring system. At this time, the communication antenna is the limit switch 180, 190 It may be configured to receive the danger signal generated by the internal control circuit according to the switch turn on, convert it into a transmittable form, and then wirelessly transmit it to an external monitoring system.

The communication modules 18 and 19 may include a first communication module 18 and a second communication module 19 . The first communication module 18 is located a certain distance away from the initial position of the transmission rod connection pin 12 in the upper front area of the displacement measuring device 10 based on the slide groove 103 in the direction in which the girder 3 contracts. , Preferably it may be a configuration having a limit switch 180 at a position separated by a distance corresponding to the maximum allowable shrinkage of the girder 3 within a range where safety problems do not occur.

And, the second communication module 19 is a certain distance in the direction in which the girder 3 extends from the initial position of the transmission rod connecting pin 12 in the lower front area of the displacement measuring device 10 based on the slide groove 103. It may be a configuration having a limit switch 190 at a distance away from each other, preferably by a distance corresponding to the maximum permissible elongation of the girder 3 within a range where safety problems do not occur.

In another embodiment of the present invention, when the expansion/contraction displacement generated in the girder due to temperature change exceeds the allowable displacement range set for safety, the limit switch included in the communication module is switched on by the measuring needle and the internal control The danger signal is generated in the circuit and related information is delivered to the external bridge monitoring system. As a result, it is possible to quickly cope with expansion and contraction displacement outside the allowable range of the girder.

In the above detailed description of the present invention, only special embodiments have been described accordingly. However, it should be understood that the present invention is not limited to the particular forms mentioned in the detailed description, but rather it is understood to include all modifications, equivalents and substitutes within the spirit and scope of the present invention as defined by the appended claims. It should be.

1: displacement measuring device 2: shift
3: girder 10: displacement measurer
12: transmission rod connecting pin 14: transverse displacement transmission rod
16: first measurement needle 17: second measurement needle
18: first communication module 19: second communication module
102: contraction displacement measurement scale 103: slide groove
104: elongation displacement measurement scale 120, 160, 170: binding member
122: connecting link 162, 172: measuring tip
180, 190: limit switch

Claims (7)

As a device for measuring the displacement of the girder in the bridge axis direction (axial direction of the bridge) for the abutment,
a displacement measuring device installed on the upper surface of the abutment and having a measurement scale on the front side;
a transmission rod connection pin slidably coupled to a slide groove formed on one surface of the displacement measurer in a first direction parallel to the axial direction;
a transverse displacement transmission rod disposed in a second direction perpendicular to the first direction, one end fixed to the girder and the other end connected to the transmission rod connection pin;
a first measurement needle slidably coupled to the slide groove at one side of the transverse displacement transmission rod; and
A bridge superstructure comprising a bridge axis direction displacement measuring device including; a second measurement needle slidably coupled to the slide groove on the other side of the transverse displacement transmitting rod.
According to claim 1,
In the device initial setting state, the bridge superstructure bridge direction displacement measuring device is disposed so that at least a part of the first measurement needle and the second measurement needle are in contact with one side of the transmission rod connecting pin and the other side of the opposite part.
According to claim 2,
At the time of girder contraction displacement, the first measurement needle is pushed by the transmission rod connecting pin to which the transverse displacement transmission rod is connected, and moves in the direction in which the contraction displacement occurs by the amount of displacement of the girder,
A bridge superstructure bridge direction displacement measuring device in which the second measurement needle is moved in the direction in which the elongation displacement occurs by the displacement of the girder by being pushed by the transmission rod connecting pin to which the transverse displacement transmission rod is connected during girder elongation displacement.
According to claim 2,
The first measurement needle is configured so that the measurement tip faces upward in front of the displacement measurer,
The second measuring needle is a bridge superstructure bridge direction displacement measuring device configured so that the measuring tip is directed downward in front of the displacement measurer, opposite to the first measuring needle.
According to claim 4,
A bridge in which contraction displacement measurement scales are formed in the first direction on the upper front area of the displacement measurer based on the slide groove formed in the first direction, and extension displacement measurement scales are formed in the first direction on the lower front area of the displacement measurer. Displacement measuring device in the bridge axis direction of superstructure.
According to claim 1,
A colored coating layer is formed or a color sheet is attached to the surfaces of the first measuring needle and the second measuring needle,
A bridge superstructure bridge direction displacement measuring device in which the colors of the color coating layer or color sheet on the surface of the first measuring needle and the second measuring needle are different from each other.
According to any one of claims 1 to 6,
A first communication module having a limit switch is installed at a predetermined distance away from the initial position of the transmission rod connection pin in the direction of contraction of the girder in the upper front area of the displacement measuring device based on the slide groove,
Displacement in the bridge axis direction of the upper structure of a bridge in which a second communication module having another limit switch is installed at a location a certain distance away from the initial position of the transmission rod connecting pin in the direction in which the girder extends in the lower front area of the displacement measuring device based on the slide groove measuring device.

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