KR101858003B1 - Connection type apparatus for measuring gap between bridge upper structures - Google Patents

Abstract

Disclosed is a length-expanding type measuring apparatus for measuring a gap of an upper structure of a bridge for safety analysis. The length-expanding type measuring apparatus includes: a bar member; a sheet member having the other end connected to one end of the bar member; a housing including a guide member to guide the bar member, which is arranged to extend along the longitudinal direction, such that the bar member is movable along the longitudinal direction, and to guide the sheet member, which is arranged to extend in the longitudinal direction and then bent in one of first right angle directions perpendicular to the longitudinal direction, such that the sheet member is movable along the longitudinal direction and the first right angle direction; and a driving force transmitting unit for transmitting a driving force to the bar member for moving the bar member along the longitudinal direction. The housing includes a linear portion on which the bar member and a portion of the sheet member facing the longitudinal direction are located, and a bent portion on which a portion of the sheet member facing the first perpendicular direction is located. The driving force transmitting unit includes a linear driving force transmitting portion inserted into the linear portion from the other end side of the linear portion and connected to the other end of the bar member so that the outer surface thereof is screwed with the inner surface of the linear portion in such a manner that the linear driving force transmitting portion moves along the longitudinal direction according to the degree of the screw coupling caused by the relative rotation to the linear portion. The linear portion includes a connection housing block connected to the bent portion and a base housing block connected directly or indirectly to the other end of the connection housing block, and at least one expansion housing block is interposed between the connection housing block and the base housing block.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a connection type measurement apparatus capable of measuring an interval of a bridge overhead structure using a spiral method in safety diagnosis,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for precisely measuring the length of a bridge-type superstructure space for safety diagnosis which can be extended in length as required.

Generally, the upper structure of a bridge includes a slab and a girder, and the lower structure of the bridge includes an alternation and a bridge supporting the girder. Of these, the upper structure of the bridge is arranged on the lower part of the bridge so as to have a predetermined distance from the neighboring structures in consideration of the fact that the longitudinal length varies with the seasonal temperature change. For example, construction is performed so that a predetermined interval is formed between the upper structure of the bridge and the alternation. Also, in the case of a multi-span bridge, the construction can be made so that the bridge superstructures are arranged adjacent to each other at predetermined intervals along the longitudinal direction. If the distance between the upper structures of the upper structures of the bridge and the upper structure of the bridge is spaced by a predetermined distance, the running feeling of the vehicles traveling on the bridge is lowered and the possibility of accidental occurrence of the accident is not excluded. An expansion joint is installed between the slabs.

In this regard, attention has recently been paid to the technique for measuring the spacing between the upper structures of bridges, and in particular, the spacing between the girders and the girders supported by the bridge supports of the lower structure, The distance between the girder and the girder or the distance between the girder and the turn can be more easily measured in order to determine whether maintenance is necessary or not, Demand for technology that can be used is expected to increase.

Korean Patent Registration No. 10-0636897 discloses a conventional apparatus for measuring the safety of bridge extension and contraction. However, the above-mentioned conventional technique is a technique for measuring the distance between the slab and the slab, and is not an interval measurement technique based on a girder actually supported by a bridge support. In addition, in the above-mentioned prior art, each of the detection sensor and the detection bar must be fixedly installed between the slab and the slab, which is covered with the expansion joint device, and a check signal lamp connected to the detection sensor and the wired line should be disposed on the bridge slab . As described above, the prior art requires a large number of configurations for generating and sensing electric signals, and there are many matters to be considered in its arrangement position and interconnection, so that the structure is complicated, installation is difficult, and simplicity in measurement .

It is an object of the present invention to solve the problems of the prior art described above, and it is an object of the present invention to provide a bridge structure having a simple structure, And the interval between alternations), and in some cases, even if the user does not go directly to the piers or alternations, the interval of the bridge superstructure can be measured on the track observer using the long extension length of the interval measuring device And an object of the present invention is to provide an apparatus for precisely measuring the length of a bridge-type superstructure space for safety diagnosis that can be accurately operated and measured.

According to a first aspect of the present invention, there is provided a connection type measuring device capable of measuring a distance between upper and lower bridges using a helical method at the time of safety diagnosis, comprising: a bar member; A sheet member whose other end is connected to one end of the bar member; Wherein the bar member is arranged to extend along the longitudinal direction so as to be movable along the longitudinal direction and to be bent and extended in one direction out of a first right angle direction perpendicular to the longitudinal direction, A housing including a member guide portion for guiding the sheet member movably along the longitudinal direction and the first right angle direction; And a driving force transmitting unit for transmitting a driving force for moving the bar member along the longitudinal direction to the bar member, wherein the sheet member includes a first member which is bent in one direction among the first right angle direction in the longitudinal direction, Wherein the member guide portion has a bending elasticity that is selectively bendable in the first bending direction only when the bending moment acting on the bending direction is equal to or greater than a reference bending moment and is resiliently restored when the bending moment action exceeding the reference bending moment is released, And a bending portion that applies a bending moment of at least the reference bending moment to the sheet member to guide a part of the sheet member to bend and bend toward one of the first right angle direction in the longitudinal direction, A linear portion in which the portion of the sheet member facing the longitudinal direction is located, Wherein the driving force transmitting unit is inserted into the linear portion from the other end side of the linear portion and connected to the other end of the bar member, And a linear driving force transmitting portion which is screwed with the inner surface of the linear portion and moves along the longitudinal direction according to the amount of screwing by the relative rotation with respect to the linear portion, wherein the linear portion includes a connecting housing block connected to the bent portion, And a base housing block directly or indirectly connected to the other end of the connection housing block, wherein at least one expansion housing block can be disposed between the connection housing block and the base housing block, At least a part of which is disposed in the inside of the sheet member, And a base bar member at least partially disposed within the base housing block and having one end directly or indirectly connected to the other end of the connecting bar member, wherein the base housing block is provided with the driving force transmitting unit The base bar member is mounted to transmit the driving force for moving the base bar member along the longitudinal direction to the base bar member, and when the extending housing block is disposed, At least a part of an extension bar member connected at one end to the other end of the connecting bar member is disposed and the linear driving force transmission unit is rotatably provided with respect to a shaft extending in the other direction from the bar member, In order to prevent the rotational force from being transmitted to the bar member It may be connected to the material.
In the connection type measuring device capable of measuring the interval of the bridge superstructure using the spiral method in the safety diagnosis according to an embodiment of the present invention, a first scale system is formed on the outer surface of the linear part along the longitudinal direction, And a reference member that is connected to the driving force transmitting portion and moves along the longitudinal direction in association with the movement of the linear driving force transmitting portion, wherein the bent portion of the housing, when the bar member is moved along one direction of the longitudinal direction, Wherein the reference member includes an end hole through which the sheet member passes in one of the first right angle directions so that a part of the member protrudes in the form of a cantilever in one direction of the first right angle direction, The length of the cantilever portion protruding from the sheet member in the first perpendicular direction A distance correction value in consideration to be provided to point.
In the connection type measurement apparatus capable of measuring the interval of the bridge superstructure using the helical system in the safety diagnosis according to an embodiment of the present invention, the reference member is formed so as to surround the outer surface of the linear portion in the circumferential direction, A second scale system may be formed along the circumferential direction, and the second scale system may have a unit smaller than that of the first scale system.
In a connection type measuring apparatus capable of measuring the interval of a bridge upper structure using a helical system in a safety diagnosis according to an embodiment of the present invention, the sheet member may have a length And a width in a second right angle direction perpendicular to the first right angle direction is larger than a thickness in the first right angle direction and an intermediate portion is convex in the other direction among the first right angle direction, The curvature of the sheet member in the curvature portion can be more easily curved than the curvature sheet in the curvature sheet shape convex in one direction among the first right angle direction by the setting of the curved sheet shape convex toward the other of the first right angle direction Lt; / RTI >
In a connection type measuring apparatus capable of measuring a bridge upper structure spacing using a helical method in the safety diagnosis according to an embodiment of the present invention, the lengthwise direction of the housing is measured in the lateral direction or the skew ) Direction, the first right angle direction corresponds to a horizontal direction orthogonal to the longitudinal direction or the square direction of the bridge top structure, the second right angle direction corresponds to the vertical direction, and the sheet member corresponds to the one direction Wherein the cantilever portion including the end member protrudes to the maximum from the end hole, wherein the cantilever portion including the end member protrudes to the maximum from the end hole , The cantilever portion protruding to the maximum by the torsion acting by the self weight of the sheet member may be provided so as not to be twisted The.
In the connection type measuring device capable of measuring the interval of the bridge superstructure using the helical system in the safety diagnosis according to an embodiment of the present invention, the length of the cantilever portion protruding to the maximum can be measured by measuring the interval of the general bridge excluding the long bridge The length can be set to 50 cm or less.
In the connection type measuring apparatus capable of measuring the interval of the bridge upper structure using the helical system in the safety diagnosis according to an embodiment of the present invention, the cross section of the sheet member is such that the cantilever portion including the end member reaches the maximum The protruding cantilever portion may be provided such that the reference bending moment is larger than a maximum bending moment that can be exerted by its own weight.
In the connection type measuring device capable of measuring the interval of the bridge upper structure using the helical method in the safety diagnosis according to an embodiment of the present invention, the bending portion may be formed at a portion of the sheet member facing the first perpendicular direction, The rotation about the second right angle direction with respect to the linear portion is possible so that the curved portion of the sheet member can be straightened.
In a connection type measuring apparatus capable of measuring a bridge upper structure gap using a helical system in a safety diagnosis according to an embodiment of the present invention, the housing has an outer surface, on which the housing is installed between two bridge superstructures or between bridge superstructures An insertion length indicator may be formed to indicate the inserted length.
In the connection type measuring device capable of measuring the interval of the bridge upper structure using the helical system in the safety diagnosis according to an embodiment of the present invention, one end of the base bar member is connected to the other end of the connecting bar member, And the magnitude of the magnetic force or the wedge coupling may be set to be larger than the magnitude of the driving force so that the movement of the base bar member can be interlocked with the connecting bar member or the extending bar member .
In a connection type measuring apparatus capable of measuring a bridge upper structure gap using a spiral method in a safety diagnosis according to an embodiment of the present invention, the base housing block is connected to the connection housing block or the expansion housing block through a screw connection, And one end of the base bar member may be connected to the other end of the connecting bar member or the other end of the extending bar member when a screw is engaged.
In a connection type measuring device capable of measuring a distance between upper and lower bridges using a helical method in a safety diagnosis according to an embodiment of the present invention, Wherein the extension bar member is movably disposed along the longitudinal direction within a range that at least part of the extension bar member remains within the extension housing block, Wherein the base bar member, the extension bar member, and the connection bar member are movably arranged along the longitudinal direction within a range in which the cantilever portion remains at the maximum, , A length longer than a length of the cantilever portion protruding to the maximum .

The above-described task solution is merely exemplary and should not be construed as limiting the present disclosure. In addition to the exemplary embodiments described above, there may be additional embodiments in the drawings and the detailed description of the invention.

According to the above-mentioned problem solving means of the present invention, since the one end of the sheet member is moved toward one of the first right angle directions as the bar member moves in one direction in the longitudinal direction, the housing can be moved in the lateral direction (Or alternately with the bridge upper structure) so that the first perpendicular direction in which one end of the sheet member moves is a horizontal direction orthogonal to the longitudinal direction of the bridge upper structure, The distance between the bridge superstructures can be easily measured through the amount of movement of one end of the sheet member. According to this, it is possible to easily, safely and precisely measure the gap between the girder and the girder which is difficult to access, such as the space between the girder and the girder. In addition, since the measurement can be performed by only a simple mechanical operation without using an electrical signal or an operation, an interval measuring apparatus can be realized which is easy to carry, manufacture and repair.

According to the above-mentioned problem solving means of the present invention, in accordance with the amount of threading between the linear portion due to the relative rotation of the linear driving force transmitting portion with respect to the linear portion, the linear driving force transmitting portion and the linear driving force transmitting portion, The operation and the interval measurement can be made more precisely and stably by adjusting the amount of movement of one end of the sheet member through the adjustment of the amount of rotation of the linear driving force transmitting portion.

According to the above-mentioned problem solving means of the present invention, it is possible to utilize a device in which the direction orthogonal to the direction to be actually measured is used as a main direction, and when the cantilever- Since the member is provided so as not to bend or twist, precise gap measurement is possible even through a simple structure. In some cases, even if the user does not go directly to the bridge pier or alternation, the interval of the bridge overhead structure can be measured on the track observer by using the long extension length of the interval measuring device.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic conceptual view illustrating a state in which a length-expandable bridge superstructure space precision measuring apparatus for safety diagnosis according to an embodiment of the present invention is viewed from one side and a part of structures disposed inside the housing are projected. FIG.
FIG. 2 is a schematic conceptual view showing a state in which the length-expanding bridge superstructure space precision measuring apparatus for safety diagnosis according to an embodiment of the present invention is viewed from above, in which some structures disposed inside the housing are projected.
FIG. 3 is a schematic conceptual diagram for explaining a method of measuring a gap with respect to a bridge superstructure through the movement of a bar member and a sheet member in an apparatus for precisely measuring the length of an extended bridge type superstructure space for safety diagnosis according to an embodiment of the present invention to be.
4 is a schematic cross-sectional view showing a driving force transmitting unit combined with a linear portion to explain a driving force transmitting unit of an apparatus for precisely measuring a gap length of a bridge-type superstructure space for safety diagnosis according to an embodiment of the present invention.
FIG. 5 is a schematic diagram for explaining an insertion length display unit and an interval display unit of the apparatus for precisely measuring the length of an extension-type bridge superstructure space for safety diagnosis according to an embodiment of the present invention.
FIG. 6 is an enlarged view of a sheet member in a portion A of FIG. 2 in a three-dimensional view to explain a convex curved sheet shape of a sheet member of a length-expandable bridge upper structure gap precision measuring apparatus for safety diagnosis according to an embodiment of the present invention .
FIG. 7 is a schematic diagram for explaining a longitudinal directional leveling unit and a first rectangular-directional leveling unit of the length-expanding bridge-type superstructure space precision measuring apparatus for safety diagnosis according to an embodiment of the present invention.
FIG. 8 is a schematic diagram for explaining that the bending portion of the length-expandable bridge superstructure space precision measuring apparatus for safety diagnosis according to an embodiment of the present invention is rotated with respect to the linear portion.
FIG. 9 is a schematic diagram for explaining a length-expanding structure of a length-expanding bridge superstructure space interval measuring apparatus for safety diagnosis according to an embodiment of the present invention.
FIG. 10 and FIG. 11 are views for explaining the relationship between the bar members (between the base bar member and the extension bar member, two extensions Between the bar member, between the extension bar member and the connection bar member, between the base bar member and the connection bar member, and the like).

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It should be understood, however, that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, the same reference numbers are used throughout the specification to refer to the same or like parts.

Throughout this specification, when a part is referred to as being "connected" to another part, it is not limited to a case where it is "directly connected" but also includes the case where it is "electrically connected" do.

It will be appreciated that throughout the specification it will be understood that when a member is located on another member "top", "top", "under", "bottom" But also the case where there is another member between the two members as well as the case where they are in contact with each other.

Throughout this specification, when an element is referred to as "including " an element, it is understood that the element may include other elements as well, without departing from the other elements unless specifically stated otherwise.

BACKGROUND OF THE INVENTION 1. Field of the Invention [

Hereinafter, an apparatus for precisely measuring the length of a bridge-type superstructure space for safety diagnosis according to an embodiment of the present invention will be described.

The gap measuring device is a device for measuring the distance between two bridge superstructures (500) or alternating with bridge superstructure (500) for safety diagnosis. For example, the gap measuring device can measure the distance between bridge girders or the gap between bridge girders and alternating walls (alternating walls). As another example, the gap measuring device can be utilized to measure the gap between the slab and the slab or the gap between the slab and the alternating wall (wall surface) as necessary. In addition to the bridge superstructure 500, the gap measuring apparatus can be used to measure the spacing between various structures and structures. Illustratively, the bridge girder may be, but is not limited to, a beam girder, a box girder, and the like. In addition, the bridge girder may be a concrete girder, a steel girder, or the like when viewed from the material side, but is not limited thereto.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic conceptual view showing a state in which a length-expanding bridge upper structure gap precision measuring apparatus for safety diagnosis according to an embodiment of the present invention is viewed from one side, FIG. 3 is a schematic view showing a state in which the length-expanding bridge superstructure space precision measuring apparatus for safety diagnosis according to an embodiment is viewed from above, in which some constructions arranged inside the housing are projected. FIG. 3 is a schematic view of an apparatus for precisely measuring the length of a bridge-type superstructure space for safety diagnosis according to an embodiment of the present invention. FIG. 3 is a schematic view for explaining a method of measuring a gap with respect to a bridge superstructure through movement of a bar member and a sheet member. . 3, for the sake of easy understanding, illustration of some configurations (driving force transmitting units, etc.) is omitted.

Referring to Fig. 1, this gap measuring apparatus includes a bar member 1. Fig.

Further, referring to Fig. 1, the apparatus for measuring the gap includes a driving force transmitting unit 4. The driving force transmitting unit 4 transmits the driving force for moving the bar member 1 along the longitudinal direction to the bar member 1. [ When the driving force is transmitted to the bar member 1 by the driving force transmitting unit 4, the linear movement of the bar member 1 relative to the longitudinal direction of the housing 3 (the direction of 12 o'clock -6 o'clock in Figs. 1 and 2) Movement can be made. In other words, the driving force acting by the driving force transmitting unit 4 is transmitted to the bar member 1, so that the movement of the bar member 1 can be achieved. Illustratively, the driving force can be provided to the bar member 1 through the driving force transmitting unit 4 by a user (gap gauge for safety diagnosis) using the gap measuring device. The driving force transmitting unit 4 will be described later in detail.

The bar member 1 can transmit the transmitted driving force to the sheet member 2 to be described later. 3, when the bar member 1 is moved in one direction of the longitudinal direction (the direction of 6 o'clock in Fig. 3) by the driving force, one end of the bar member 1 is in contact with the other end of the sheet member 2 The sheet member 2 can also be moved in one of the longitudinal directions while pressing the sheet member 2 in one direction of the longitudinal direction. As will be described later, unlike the sheet member 2 in which the bending direction is switched, the bar member 1 is configured to linearly move along the longitudinal direction to transmit the driving force to the sheet member 2, It is preferable to be made of a rigid material having a predetermined rigidity so as to be clearly transmitted to the sheet member 2. Illustratively, the bar member 1 may be of plastic material, but is not limited thereto. That is, in view of the role of linear driving force transmission, it is preferable that the bar member 1 is provided in a less flexible (less flexible) material and a cross-sectional shape in warpage than the sheet member 2.

Further, referring to Fig. 1, this gap measuring apparatus includes a sheet member 2. The other end of the sheet member (2) is connected to one end of the bar member (1). 2, the sheet member 2 is selectively bendable in the first bending direction only in the first bending direction bent in one direction among the first perpendicular direction in the longitudinal direction, and only when the bending moment acts at a reference bending moment or more And has a flexural elasticity that is restored to its original elasticity upon releasing a bending moment acting beyond a reference bending moment. Illustratively, the sheet member 2 may be a flexible steel sheet, a flexible plastic sheet, a leaf spring member, or the like having the above-mentioned flexural elasticity.

1 and 2, the apparatus for measuring the gap includes a housing 3. 2, the housing 3 includes a linear portion 31 in which a bar member 1 and a portion facing the longitudinal direction of the sheet member 2 are positioned, and a linear portion 31 extending in the first perpendicular direction of the sheet member 2 And a bent portion 32 on which the portion is located.

4 is a schematic cross-sectional view showing a driving force transmitting unit combined with a linear portion to explain a driving force transmitting unit of an apparatus for precisely measuring a length of an extended bridge type superstructure space for safety diagnosis according to an embodiment of the present invention, FIG. 2 is a schematic diagram for explaining an embodiment of an insertion length display unit and an interval display unit of a length-expanding bridge top structure gap precision measuring apparatus for safety diagnosis according to an embodiment of the present invention.

4, the driving force transmitting unit 4 is inserted into the linear portion from the other end side of the linear portion 31 and connected to the other end of the bar member 1, (For example, a male thread can be formed on the outer surface of the driving force transmitting unit 3 and a female thread can be formed on the inner surface of the linear portion 31) And a linear driving force transmitting portion 41 which moves along the longitudinal direction according to the amount of screw connection by relative rotation with respect to the linear driving force transmitting portion 41. Illustratively, a user using the gap measuring device rotates the linear driving force transmitting portion 41 relative to the linear portion 31 to adjust the amount of screwing between the linear driving force transmitting portion 41 and the linear portion 31 The linear driving force transmitting portion 41 can be advanced along one direction of the longitudinal direction and the linear driving force transmitting portion 41 can be moved in the longitudinal direction of the bar member 1 with respect to the longitudinal direction of the housing 3 Linear movement can be achieved. In other words, the driving force applied to the linear driving force transmitting portion 41 is transmitted to the bar member 1, so that the movement of the bar member 1 can be achieved.

According to this driving force transmitting unit 4, the amount of movement in the longitudinal direction of the bar member 1 is determined by the amount of thread engagement between the linear driving force transmitting portion 41 and the linear portion 31, The amount of movement of one end of the sheet member 2 can be adjusted, so that the operation and the interval measurement can be made more precisely and stably. According to this, since the linear driving force transmitting portion 41 can be moved by the helical method in accordance with the threaded engagement with the linear portion 31, the gap measuring device can measure the beam interval using the helical method in the safety diagnosis, Device.

For reference, the linear driving force transmitting portion 41 can be connected to the bar member 1 such that the rotational force of the linear driving force transmitting portion 41 is not transmitted to the bar member 1. [ Accordingly, even if the linear driving force transmitting portion 41 is rotated, the bar member 1 can be moved in the longitudinal direction without being rotated or twisted. 4, the linear driving force transmitting portion 41 is provided so as to be rotatable with respect to a shaft 19 extending from the bar member 1 in the other direction, so that its rotational force is transmitted to the bar member 1 It can be connected to the bar member 1 so as not to be transmitted.

The driving force transmitting unit 4 may include a handle 43 having a friction pattern formed on its outer surface so that the user can rotate the linear driving force transmitting portion 41 easily.

5, the driving force transmitting unit 4 includes a reference member 42 connected to the linear driving force transmitting portion 41 and moved along the longitudinal direction in association with the movement of the linear driving force transmitting portion 41 can do. As described above, since the movement of the bar member 1 is performed in accordance with the movement of the linear driving force transmitting portion 41, the reference member 42 is moved by interlocking with the bar member 1, The measured interval can be indicated (displayed). This will be described in detail later.

Further, illustratively, according to the present gap measuring apparatus, at least a part of the linear portion 31 may have a circular cross section. For example, the inner surface of the portion where the linear driving force transmitting portion 41 of the linear portion 31 is inserted may be circular in cross section. More specifically, the inner surface of the portion of the linear portion 31 that is threadedly engaged with the inner surface of the linear driving force transmission portion 31 has a circular cross-section for screw connection, and the above-mentioned male thread is formed on the inner surface. Further, illustratively, the outer surface of the portion to be wrapped by the reference member 42 (described later) of the linear portion 31 may have a circular cross-section. Accordingly, the reference member 42 can be rotated with respect to the linear portion 31 in association with the rotation of the linear driving force transmitting portion 41. [ As described above, according to the present gap measuring apparatus, since at least a part of the linear portion 31 can be realized as a circular cross section, the driving force transmitting unit 4 which can be easily operated can be realized. However, the portion of the linear portion 31 having a circular cross section is not limited to such a portion, and the inner surface or outer surface of the various portions of the linear portion 31 may have a circular cross section if necessary. For example, the outer surface of each portion where the connection between the base housing block 312, the connection housing block 311 and the expansion housing block 313 of the linear portion 31 to be described later is made, the outer surface of the other end of the linear portion 31 The outer surface or the like may have a circular cross section. Alternatively, if necessary, the linear portion 31 may be formed in a shape in which the entire inner or outer surface has a circular cross-section.

1, the housing 3 includes a bar member 1 which is arranged to extend along the longitudinal direction and which guides the bar member 1 movably along the longitudinal direction, extends along the longitudinal direction (one direction in the longitudinal direction) And a member guide portion (5) for guiding the sheet member (2) arranged to extend in one direction out of a first right angle direction orthogonal to the longitudinal direction so as to be movable along the longitudinal direction and the first right angle direction.

2, the bar member 1 may be arranged to extend along the longitudinal direction within the linear portion 31 of the housing 1, the sheet member 2 may be positioned within the linear portion 31, May be disposed so as to have a portion connected to one end of the bar member 1 and extending in the longitudinal direction and a portion located in the bent portion 32 and bent in one direction out of the first perpendicular direction. 3, when the bar member 1 is moved by a along the one direction in the longitudinal direction by the driving force of the driving force transmitting unit 4 in the initial arrangement state, the other end is moved to one end of the bar member 1 The connected sheet member 2 is also moved together with the bar member 1 so that a portion of the portion facing the longitudinal direction of the sheet member 2 by the member guide portion 5 is moved in the first perpendicular direction It can be moved and moved in one direction. 3, when the bar member 1 is moved by a in one direction in the longitudinal direction, the other end side of the sheet member 1 is moved by a in one direction of the longitudinal direction like the bar member 1, The one end side of the member 1 can be moved by a in one direction among the first perpendicular direction unlike the bar member 1. [

2, the member guide portion 5 applies a bending moment not less than a reference bending moment to the sheet member 2 so that a part of the sheet member 2 is bent in one direction out of the longitudinal direction, And a curved portion 51 for guiding the curved portion 51 so as to be guided. The curved portion 51 is formed in such a manner that one end side of the sheet member 2 in the movement direction of the sheet member 2 in the longitudinal direction of the bar member 1 is opposed to the other end side of the sheet member 2 in the first right angle direction The middle portion of the sheet member 2 is guided so as to be gently bent. By this curved portion 51, the direction of the sheet member 2 can be gradually switched from one to the other in the first perpendicular direction in the longitudinal direction. As described above, the sheet member 2 is provided so as not to be bent by a bending moment smaller than the reference bending moment, so that the curved shape (curved shape) of the curved portion 51 allows the sheet member 2 to bend more than the reference bending moment It is preferable that the sheet member 2 is provided in a form capable of bending the sheet member 2 gradually by applying a moment.

By way of example, the curved portion 51 may be provided in the form of a tube having a size and shape that can guide the sheet member 2 to gradually bend and move along the sheet member 2. 1 to 3, the member guide portion 5 may be provided in the form of a tube (tube) for receiving the bar member 1 and the sheet member 2, A tube extending in the longitudinal direction and a tube extending in the first perpendicular direction may be connected to each other. The curved portion 51 is disposed at a portion between the linear portion 31 and the bent portion 32 in the inside of the housing 3 so that the extending direction of the sheet member 2 is set in the longitudinal direction And may include a plurality of rollers for progressively switching one of the first direction and the second direction. That is, the curved portion 51 may be provided in the shape of a curved tube or may be provided in a plurality of roller guides arranged on both sides in the thickness direction of the sheet member 2 to induce curvature, but the present invention is not limited thereto.

The member guide portion 5 may include a gap maintaining member (stabilizer) for guiding the bar member 1 to be linearly moved without departing from the longitudinal direction of the housing 3. [ The gap holding member is formed by a bar member 1 or a bar member 2 with respect to the inner surface of the housing 3 so that the gap between the inner surface of the housing 3 and the bar member 1 or the sheet member 2 can be constantly maintained. A plurality of spacers for supporting the sheet member 2 and spaced along the longitudinal direction of the housing 3. [ Or in other embodiments, the gap holding member may be provided in such a manner as to continuously support the bar member 1 or the sheet member 2 along the longitudinal direction. Further, the gap holding member may be provided in such a manner as to support the bar member 1 and a tube (pipe) member which receives the sheet member 2. [

The width of the sheet member 2 in the second perpendicular direction perpendicular to the longitudinal direction and the first perpendicular direction (see Fig. 1, w) is set to be (See Fig. 2, t) in the first right angle direction. Accordingly, the sheet member 2 can be easily bent in one direction out of the longitudinal direction by the curved portion 51, and can not easily be bent from the longitudinal direction toward the second perpendicular direction .

FIG. 6 is an enlarged view of a sheet member in a portion A of FIG. 2 in a three-dimensional view to explain a convex curved sheet shape of a sheet member of a length-expandable bridge upper structure gap precision measuring apparatus for safety diagnosis according to an embodiment of the present invention .

6, the sheet member 2 may have a curved sheet-like cross-section in which the middle portion is convex in the other direction (10 o'clock direction in Fig. 6) in the first right angle direction. The sheet member 2 is configured such that the sheet member 2 at the curved portion 51 in the curved sheet shape is convex in the first perpendicular direction, 2 can be easily induced.

3, when the bar member 1 is moved along one direction in the longitudinal direction, a part of the sheet member 2 is cantilevered in one direction of the first perpendicular direction, And an end hole 33 through which the sheet member 2 passes in one direction out of the first right angled direction so as to protrude in the form of a protrusion.

3, when the bar member 1 is moved along one direction of the longitudinal direction by the driving force of the driving force transmitting unit 4, the other end is brought into contact with the sheet member 1 connected to one end of the bar member 1, The member 2 is moved by the transmitted driving force and the portion of the sheet member 2 which faces the longitudinal direction can be shifted and moved in one direction of the first perpendicular direction. The length of the portion extending in one direction in the first perpendicular direction of the sheet member 2 can be increased and the one end of the sheet member 2 passes through the end hole 33 to the outside of the housing 3 It can be protruded in the form of a cantilever. In other words, as the sheet member 2 moves, the length of the portion extending in one direction in the first perpendicular direction of the sheet member 2 can be increased, and as the length is increased, the portion of the protruding portion in the form of the cantilever The length can be increased. In other words, the length a of the portion projecting in the form of the cantilever corresponding to the amount of advancement (a) in one direction in the longitudinal direction of the bar member 1 can be increased.

3, in the measurement of the gap, the longitudinal direction of the housing 3 may correspond to the lateral direction or the skew direction of the bridge superstructure 500. At this time, the first right angle direction may correspond to the horizontal direction orthogonal to the longitudinal direction or the square direction of the bridge superstructure 500, and the second right angle direction may correspond to the vertical direction.

For example, if there is no skew in bridge superstructure 500, the spacing between bridge superstructures 500 (or the spacing between alternations with bridge superstructure 500) may be determined in the transverse direction of the bridge The length of the housing 3 in the direction of the length of the bridge upper structure 500 (the direction perpendicular to the longitudinal direction of the bridge upper structure 500) (Or alternating with the bridge overhead structure 500) so that the first perpendicular direction in which one end of the sheet member 2 is moved is directed to the bridge superstructure 500 (Horizontal direction) orthogonal to the lateral direction of the vehicle body 100 (see FIG. 3).

On the other hand, when there is a skew in the bridge superstructure 500, the distance between bridge supra structures 500 (or the distance between bridge superstructure 500 and alternation) is determined by the lateral direction of the bridge The direction of the longitudinal direction of the bridge 3 is not limited to the direction perpendicular to the longitudinal direction of the bridge 3 but may be defined as a distance with respect to the longitudinal direction of the bridge formed along a square direction inclined by a skew with respect to the transverse direction of the bridge. Can be disposed between the bridge superstructures 500 (or alternately with the bridge superstructure 500) so as to face in the square direction of the bridge superstructure 500, (Or alternately with the bridge superstructure 500) (see FIG. 3) such that the right angle direction is directed horizontally orthogonal to the square direction of the bridge superstructure 500.

That is, at the time of the interval measurement, the bar member 1 can be moved along the lateral direction or the skew direction of the bridge top structure 500 by the driving force of the driving force transmitting unit 4, Can be driven to move in the horizontal direction orthogonal to the longitudinal direction or the rectangular direction of the bridge superstructure 500 once. 3, the distance between the bridge superstructures 500 formed along the horizontal direction orthogonal to the longitudinal direction or the square direction of the bridge superstructure 500, or between the bridge superstructure 500 and the alternation, It can be the interval that the device measures.

An interval measurement by the interval measuring apparatus will be described as an example for the interval between the bridge superstructures 500 as follows. 3, the housing 3 can be inserted between the two bridge superstructures 500 in the transverse (or square) direction of the bridge superstructure 500, and the housing 3 can be inserted in the first right- When the bar member 1 is moved by a along one direction of the longitudinal direction in a state in which the outer surface facing the other direction is in contact with the wall surface of one of the two bridge superstructures 500 facing each other at an interval, The portion of the sheet member 2 facing the one direction of the first perpendicular direction of the sheet member 2 has a length protruding from the end hole 33 until the one end of the sheet member 2 is in contact with the wall surface of the other of the two bridge top structures 500 a < / RTI > 3, the length c of the portion of the housing 3 facing the one direction of the first perpendicular direction and the length d of the cantilever portion protruding from the end hole 33 of the sheet member 2 ) Can be measured at the interval between the two bridge superstructures (500). The length d of the cantilever portion protruding in the form of the cantilever of the sheet member 2 corresponds to the amount of movement a of the sheet member 2 and an end portion (Da) of the first substrate 21. That is, the distance that the bar member 1 is actually moved along the longitudinal direction is a, but the measured interval corresponds to the interval compensated by considering the length (c + da) of the interval measuring apparatus facing the first right angle direction Need to be displayed. Illustratively, even if the bar member 1 moves by a from the initial state, a is not displayed in the first graduation meter 38 shown in Figs. 4 and 7 to be described later, It is preferable that the corrected value (a + c + da = c + d) is displayed in consideration of the original length of the apparatus (the sum of the length c of the housing and the thickness da of the end member). Although the spacing between the two bridge superstructures 500 is illustratively described herein, the spacing between the bridge superstructure 500 and the alternating measurement and the display of the measured values may also be the same or similar to those described above Of course it is.

That is, referring to FIG. 5, the first graduation scale 38 described above may be formed on the outer surface of the linear portion 31 along the longitudinal direction. The reference member 42 is a part of the cantilever portion protruding out of the sheet member 2 in the first graduation system 38 (a portion of the sheet member 2 protruding in the form of a cantilever in one direction among the first right angle direction) Can be formed to indicate the interval value (c + d) corrected by taking the length (d) and the length (c) of the housing 3 with respect to the first right angle direction together.

Specifically, the reference member 42 moves in conjunction with the movement of the bar member 1, and the value indicated by the final position (the position of the reference member 42 when the movement of the bar member 1 is completed) And may be displayed in the corrected interval value.

3 and 5 together, the reference member 42 is moved from the initial position (the reference member 42 before the movement of the bar member 1 is performed) on the scale of the first graduation 38 (A) of the bar member 1 after the movement of the bar member 1 has been completed, that is, the position of the bar member 1 And will be located in the final position. Therefore, the first graduation scale 38 is set such that the initial position of the reference member 42 is equal to the length c of the portion of the housing 3 facing the one direction of the first perpendicular direction of the housing 3, (The value corresponding to the length c of the portion facing the one direction of the first perpendicular direction of the housing 3 when the end member 21 is not provided) corresponding to the sum of the thicknesses So that the value indicated on the scale of the first graduation scale 38 by the reference member 42 at the final position of the reference member 42 is smaller than the corrected spacing value (in the first orthogonal direction of the housing 3) The sum of the length c of the portion facing the one direction and the length d of the cantilever portion protruding from the end hole 33 of the sheet member 2).

Illustratively, the reference member 42 may be provided to move on the first graduation scale 38. For example, referring to FIG. 5, the reference member 42 may be formed to surround the outer surface of the linear portion 31 in the circumferential direction. Alternatively or in addition, the reference member 42 may be provided to move and indicate graduations of the first scaling system 38 on the side of the first scaling system 38.

It is preferable that the first graduation system 38 and the reference member 41 are provided as close as possible to the other end side of the longitudinal direction of the housing 3 (the end side in the reference 12 o'clock direction in Fig. 5). In other words, the first graduation system 38 and the reference member 41 are designed so that the length-extension type bridge superstructure space precision measuring apparatus for safety diagnosis is inserted deeply between the two bridge superstructures 500 or alternately with the bridge superstructure 500 It is desirable that the user can easily check the scale even in a state where the user is in a state of being in a state of being in a state of being opened. Accordingly, even when the interval measuring apparatus is inserted deeply into the space between the intervals to be measured, the interval displayed outside the space can be easily read.

In addition, the first graduation scale 38 can be adjusted to zero to eliminate errors as needed. There may be some fluctuations in the initially set c value, (d-a) value, etc., depending on the seasonal change, the temperature change, and the like. In consideration of the possibility of such an error, the first graduation scale 38 may be provided so as to be able to adjust the zero point. For example, the first graduation scale 38 may be provided so that the graduation line and the graduation display value are moved differently in the longitudinal direction relative to each other, but the zero scale adjustment method of the first graduation scale 38 is limited thereto no. Illustratively, the first scale system 38 may be provided with a scale system movably along the longitudinal direction. The first graduation system 38 is arranged so that the first graduation 38 is directed toward one direction out of the first perpendicular direction of the housing 3 when the bent portion 32 is bent and arranged with respect to the linear portion 31 (In the case where the end member 21 is not provided, a portion of the portion facing the one direction of the first perpendicular direction of the housing 3) corresponding to the sum of the length c of the portion and the thickness of the end member 21 The value corresponding to the length (c)) can be zero pointed so that the initial position of the reference member 42 can indicate.

5, when the reference member 42 is formed so as to surround the outer surface of the linear portion 31 in the circumferential direction, the outer surface of the reference member 42 is provided with a second graduation scale 421 May be formed. The second scale 421 may have a smaller (lower) unit than the first scale 38. As described above, the linear driving force transmitting portion 41 can be screwed to the linear portion 31. At this time, the thread formed on the linear driving force transmitting portion by the rotation of the linear driving force transmitting portion 41 is engaged with the linear portion 31 31, and the linear driving force transmitting portion 41 can move in the longitudinal direction. The reference member 42 can be rotated in association with the rotation of the linear driving force transmitting portion 41. [ The value indicated by the reference line formed in the longitudinal direction on the linear part 31 among the values on the second scale system 321 is smaller than the fine unit value of the corrected interval value Small unit value). For example, the first scale system 38 may have a unit of 1 mm, and the second scale system 421 may have a unit of 0.01 mm. As another example, the first scale system 38 may form a scale in units of 1 cm, and the second scale system 421 may form a scale in units of 1 mm. That is, the calibrated interval value can be grasped more precisely by comprehensively referring to the value measured through the first graduation meter 38 and the value measured through the second graduation meter 421.

5, an outer surface of the housing 3 is provided with an insertion length indicator portion (not shown) for indicating the length of insertion of the housing 3 between the two bridge superstructures 500 or alternately with the bridge superstructure 500 39 may be formed. By measuring the insertion length of the housing 3 through the insertion length display portion 39, it is possible to separately measure and record the intervals of each position in the transverse direction or the square direction of the bridge. For example, if the girder is inserted 1 m apart from the girder, the gap between the girders, the gap between girders when inserted 2 m, and the gap between girders when girders are inserted 3 m, Reliable and sophisticated. That is, according to the present invention, it is possible to measure only the inter-girder spacing that can be grasped from the outside of the girder (outside in the lateral direction), and furthermore, to measure the inter-girder spacing The interval can be accurately measured. Illustratively, according to the present invention, even for a bridge superstructure having a transverse width, such as a 3-BEAM girder, or a bridge superstructure in which a plurality of girders are arranged at intervals along the transverse direction, The distance between the girders can be measured separately. In consideration of the bridge superstructure having such a wide width, the interval measuring apparatus may be provided in an extended form, which will be described later.

The insertion length display section 39 is provided with the insertion length display section 39 so that the user can check whether or not the length extension type bridge superstructure space precision measuring device for safety diagnosis is deeply inserted between the two bridge superstructures 500 or between the bridge superstructure 500 It is preferable to be provided so as to be easy. For example, referring to FIG. 5, the insertion length indicator may include a scale, in which the final value corresponding to the inserted length is directed toward the other end of the scale (the end in the other direction of the length of the housing) In other words, as the number of digits on the scale increases toward the other end of the scale system, the user can easily confirm the insertion length outside the bridge superstructure.

1 and 2, the sheet member 2 may include an end member 21 at one end of which a normal line of the surface is formed with an end face oriented in one direction of the first perpendicular direction. As described above, one end of the sheet member 2 may be in contact with the wall surface of one of the two bridge superstructures 500, for the spacing measurement between the two bridge superstructures 500. The contact area between one end of the sheet member 2 and the wall surface is increased by the end member 21 and one end of the sheet member 2 can be stably supported on the wall surface.

The cross section of the sheet member 2 is a part of the sheet member 2 which protrudes to the maximum by the torsion acting by the self weight of the sheet member 2 when the cantilever portion including the end member 21 protrudes from the end hole 33 at the maximum So that the cantilever portion is not twist-deformed. 3, when the gap measuring device is inserted into the space to be measured, the sheet member 2 is disposed in a standing state such that the width w of the sheet member 2 is wider than the thickness t . Even if the sheet member 2 protrudes in the form of a cantilever (cantilever) for measuring the interval, the moment of inertia of the cross section against the moment to be bent by its own weight becomes very large according to the raised cross-sectional shape, The possibility of bending of the cantilever portion due to warping in use of the apparatus is relatively small. However, it is necessary to consider the possibility that the torsional deformation is generated by a torsion or the like, which is acted on by the end member 21 or the like protruding in the longitudinal direction, have. That is to say, the cantilever portion including the end member 2 is deformed by the self weight of the cantilever portion with respect to the amount of protrusion (the length of the cantilever portion protruding to the maximum) at which the sheet member 2 can protrude to the maximum from the end hole 33 It is preferable that the cross section of the sheet member 2 is set. In order to have a high resistance to such a torsion, the sheet member 2 may be provided in a convex curved sheet shape as described above. Accordingly, even if the cantilever is protruded, the cantilever can protrude more than a predetermined amount without any warping or twisting. Thus, even if only the simple structure is used, the distance between the two bridge superstructures 500 or the gap Can be accurately measured. The sheet member 2 also has a thickness in the form of a convex curved sheet such that the end member 21 has a cross sectional dimension that can withstand the predetermined impact applied when it is contacted with the opposite wall surface of the bridge top structure 500, Width, material, and the like are preferably set. Here, the predetermined impact is a phenomenon in which the user of the gap measuring device operates the driving force transmitting unit 4 to advance the bar member 1 in one direction in the lengthwise direction, When the forward movement is interrupted due to the feeling of resistance that the bar member 1 is difficult to further advance by being in contact with the opposing wall surface of the bar member 500, it may mean an amount of impact corresponding to the resistance.

The cross section of the sheet member 2 is set such that the cantilever portion including the end member 21 protrudes to the maximum from the end hole 33, The reference bending moment is larger than the bending moment.

In addition, the length of the cantilever portion protruding to the maximum can be set to 50 cm or less, which is a measurable length of the interval of the general bridge excluding the long bridge. Preferably, the length of the cantilever portion protruding to the maximum can be set to 30 cm or more and 50 cm or less. (The distance between the two bridge superstructures 500 or the distance between one bridge superstructure 500 and the second bridge superstructure 500) where the sum of the length of the housing 3 with respect to the first right angle direction and the length of the cantilever portion protruding to the maximum is measured, The sum of the length of the housing 3 with respect to the first right angle direction and the length of the cantilever portion protruding at the maximum is set to 50 cm or less (preferably 30 cm to 50 cm) . Illustratively, the length of the housing 3 with respect to the first right angle direction is set to 5 cm to 20 cm as the minimum value of the interval in the general bridge, and the length of the housing 3 with respect to the first right angle direction and the maximum The sum of the lengths of the cantilever portions that can protrude from the cantilever can be set to 30 cm to 50 cm. As described above, when the general-purpose bridge excluding the long bridge is applied, only the length of the sheet member 2 from the end hole 33 is limited to about 50 cm. Therefore, the above- And this sheet cross section is used in the form of standing in the vertical direction and has a high bending resistance against bending moment due to its own weight, it is possible to measure easily and precisely through a simple protruding structure in the form of a cantilever Do.

FIG. 7 is a schematic diagram for explaining a longitudinal directional leveling unit and a first rectangular-directional leveling unit of the length-expanding bridge-type superstructure space precision measuring apparatus for safety diagnosis according to an embodiment of the present invention.

Referring to FIG. 7, the gap measuring apparatus includes a longitudinal directional leveling unit 3a provided to indicate that the linear portion 31 is horizontal when it is oriented in the horizontal direction, And a first right angle directional leveling unit 3b which is provided to indicate that it is horizontal when it is oriented in the direction of the arrow.

The longitudinal directional leveling device 3a and the first right angle directional leveling device 3b are used to insert a length-extending bridge superstructure space precision measuring device for safety diagnosis deeply between the two bridge superstructures 500 or alternately with the bridge superstructure 500 It is desirable that the user can easily check the scale even in a state where the user is in a state of being in a state of being in a state of being opened. Illustratively, the longitudinal directional leveling device 3a and the first orthogonal directional leveling device 3b may be provided on the outer surface of the tip end portion of the driving force transmitting unit 4. Further, by way of example, various horizontal systems that can be used conventionally can be applied to the longitudinal directional level 3a and the first right-angled directional level 3b. For example, a water level can be applied to these levels. By adjusting the horizontal level by combining these two leveling systems, it is possible to measure the horizontal distance between the bridges superstructure (or the bridge superstructure and the alternation interval) So that the recording of the measurement position and the measurement interval for the safety diagnosis can be made more accurately.

FIG. 8 is a schematic diagram for explaining that the bending portion of the length-expandable bridge superstructure space precision measuring apparatus for safety diagnosis according to an embodiment of the present invention is rotated with respect to the linear portion.

As described above, the housing 3 has the linear portion 31 in which the bar member 1 and the portion facing the longitudinal direction of the sheet member 2 are positioned, and the linear portion 31 in the direction of the first right angle of the sheet member 2 8, the folding portion 32 is formed so that the portion of the sheet member 2 facing the first perpendicular direction faces the longitudinal direction of the sheet member 2, and the folded portion 32 of the sheet member 2 Can be rotated about the second orthogonal direction with respect to the linear portion 31 so that the curved portion of the linear portion 31 can be straightened. That is, the interval measuring apparatus may be provided in a foldable type. For example, referring to FIG. 8, the bent portion 32 may be hinged 34 to be rotatable about the second perpendicular direction with respect to the linear portion 31. Thus, the reduction in durability of the sheet member 2 can be minimized. For example, when the folded state of the sheet member 2 is maintained for a long period of time, the elastic restoring force against the bending of the bent portion of the sheet member 2 is lowered and a part of the plastic deformation is completed, There is a possibility that the difficulty of protruding from the hole 33 in a partially bent state can not be generated. In consideration of this aspect, the sheet member 2 is maintained in a straight linear state rather than maintaining a partially curved state at an extra-measurement time (storage time, moving time, etc.) It is possible to more fundamentally prevent the measurement accuracy from decreasing due to the plastic deformation of the substrate 2. According to this, the gap measuring apparatus can be called a bridge superstructure extended folding gap precision measuring apparatus for safety diagnosis.

  The housing 3 may also have a limit block that prevents the bent portion 32 from spreading at an angle greater than 90 degrees with respect to the linear portion 31. [ 8, a limit block is disposed outside the hinge shaft 34 connecting the bending portion 32 and the linear portion 31 to restrict the bending portion 32 to rotate only in a direction perpendicular to the hinge axis 34 . The limit block and the bending portion 32 may be provided with a unit structure that can be mutually fixed through a magnetic force coupling, a wedge coupling, or the like when they are partially in contact with the surface of the bending portion 32. The term "temporarily fixed" may mean a coupling having a fixing force not to be separated unless a user applies a predetermined external force (an external force for separating the bent portion 32 from the limit block). This temporary rigid coupling can be understood to be the same as or similar to the coupling method between the bar members.

8, at the time of rotation for the bending arrangement (the arrangement in which the bending portion 32 is bent in the direction of the first right angle from the longitudinal direction) with respect to the linear portion 31 of the bending portion 32, The sheet member 1 is long enough to bend the sheet member 2 and can be slightly pulled toward one side of the direction. Taking this into consideration, the interval value indicated by the first scale system 38 is displayed on the basis of when the bent portion 32 is bent with respect to the linear portion 31 and placed in a state for interval measurement desirable. In other words, the interval value indicated by the first scale meter 38 is the length (c) of the portion facing the one direction of the first perpendicular direction with respect to the time when the sheet member 2 is placed in the state for the interval measurement, The sum of the lengths (d) of the cantilever portions protruding from the end holes 33 can be calculated. 8, the length c of the portion of the housing 3 facing the one direction of the first perpendicular direction of the housing 3 is set such that the bent portion 32 is inclined with respect to the linear portion 31 The first right angle direction from the end of the linear portion 31 of the housing 3 toward the other direction in the first right angle direction to the end of the first right angle direction of the bent portion 32 toward one direction, May refer to a length based on a direction.

Further, although not shown in detail in the drawings, the curved portion 51 is formed in a curved state in which a part of the sheet member 2 is curved and in a linear state in which the curved portion of the sheet member is straightened, And may be provided in the form of a flexible material tube in which a movable path is formed.

On the other hand, the linear portion 31 may have a rectangular cross-section with the normal of the plane having the outer surface facing the other of the first perpendicular direction. Accordingly, in the interval measurement, the outer surface of the housing 3 in the first right-angled direction facing the other direction can stably contact one wall surface of the two bridge superstructures 500.

FIG. 9 is a schematic diagram for explaining a length-expanding structure of a length-expanding bridge superstructure space interval measuring apparatus for safety diagnosis according to an embodiment of the present invention.

9, the linear portion 31 includes a connection housing block 311 connected to the bent portion 32 and a base housing block 312 directly or indirectly connected to the other end of the connection housing block 311 . Also, one or more expansion housing blocks 313 can be disposed between the connection housing block 311 and the base housing block 312. [ The extension housing block 313 can be disposed between the connection housing block 311 and the base housing block 312 so that the length extension of the linear portion 31 depends on the arrangement of the expansion housing block 313, It can be possible.

9, the bar member 1 includes a connecting bar member 11 at least partially disposed inside the connecting housing block 311 and having one end connected to the other end of the sheet member 2, And a base bar member 12 at least partially disposed inside the block 312 and having one end directly or indirectly connected to the other end of the connecting bar member 11. [ The driving force transmitting unit 4 is mounted on the base housing block 312 to transmit the driving force for moving the base bar member 12 along the longitudinal direction to the base bar member 11 and the extended housing block 313 The other end of the expansion housing block 313 is connected to one end of the base bar member 12 and at least one end of the extension bar member 13 is connected to the other end of the connection bar member 11 Can be disposed. Accordingly, the length of the bar member 1 can be extended corresponding to the extension of the linear portion 31.

One end of the base bar member 12 may be connected to the other end of the connecting bar member 11 or the other end of the extending bar member 13 by a magnetic force. One end of the connecting bar member 11 may be connected to the other end of the other connecting bar member 11 or the other end of the extending bar member 13 by the magnetic force. The magnitude of the magnetic force can be set to be larger than the magnitude of the driving force so that the movement of the base bar member 12 can be interlocked with the connecting bar member 11 or the extending bar member 13. [

FIG. 10 and FIG. 11 are views for explaining the relationship between the bar members (between the base bar member and the extension bar member, two extensions Between the bar member, between the extension bar member and the connection bar member, between the base bar member and the connection bar member, and the like).

10 and 11, one end of the base bar member 12 may have a structure connected to the other end of the connecting bar member 11 or the other end of the extending bar member 13 by wedge-engaging. One end of the connecting bar member 11 may have a structure that is connected to the other end of the other connecting bar member 11 or the other end of the extending bar member 13 by wedge joining. The size of the wedge connection can be set to be larger than the magnitude of the driving force so that the movement of the base bar member 12 can be interlocked with the connecting bar member 11 or the extending bar member 13. [

10 and 11, at the end of the wedge insertion portion inserted into the wedge recess when the wedge is engaged, a taper or a slope corresponding to the size (width) of the opening of the wedge depression is formed at the end of the wedge insertion portion, Can be formed. Although Figs. 10 and 11 show the wedge connection of the base bar member 12 and the connection bar member 11, the same wedge connection can be applied to the connection between the other bar members. In addition, the wedge joint structure in the present application is not limited to those shown in FIGS. 10 and 11, and various other types of wedge joint structures can be applied to the present interval measurement device.

9, the base bar member 12 has a length in a range in which at least a part remains within the base housing block 312 (that is, a range in which the base bar member 312 does not completely deviate from the inside of the base housing block 312) And the expansion bar member 13 is arranged to be movable in the range in which at least a part remains within the expansion housing block 313 (that is, the range in which the expansion bar block 313 is not completely deviated from the inside of the base housing block 312) And the connecting bar member 13 is disposed within the connection housing block 313 in a range where at least a part thereof remains (that is, a range in which the connecting bar member 13 is not completely separated from the inside of the base housing block 312) , And the base bar member 12, the extension bar member 13, and the connecting bar member 11 are arranged so as to be movable along the longitudinal direction at a position corresponding to the length of the cantilever portion protruding to the maximum The length of the protruded cantilever portion may be longer than the length of the protruded cantilever portion. The base bar member 12 and the extension bar member 13 can be prevented from being deformed even when one end of the sheet member 2 protrudes to the outside of the end hole 33 to the maximum (when the length of the cantilever portion becomes maximum) And at least a portion of each of the connecting bar members 11 may remain within each of the base housing block 312, the expansion housing block 313, and the connection housing block 311.

Illustratively, each of the base bar member 12, the extension bar member 13, and the connecting bar member 11 includes a base housing block 312, an expansion housing block 313, and a connection housing block 311, Preventing unit 25 from being completely deviated along the lengthwise direction. The separation preventing unit 25 can be provided at the other end of each of the base bar member 12, the extension bar member 13 and the connecting bar member 11, and the base bar member 12, Each of the member 13 and the detachment preventing unit 25 of the connecting bar member 11 can be engaged with one end of each of the base housing block 312, the extending housing block 313, and the connecting housing block 311 have. Accordingly, at least one of each of the base bar member 12, the extension bar member 13, and the connecting bar member 11, which may occur during the movement in the longitudinal direction, is received by the base housing block 312, the expansion housing block 313 One or more of the escape prevention units are connected to one end of each of the base housing block 312, the expansion housing block 313, and the connection housing block 311 before separation from each of the connection housing block 311 and the connection housing block 311 is performed, The expansion housing block 313 and the connection housing block 311 of the base bar member 12, the extension bar member 13, and the connecting bar member 11, respectively, Can be prevented from departing from each other.

Referring to FIG. 2, the housing 3 may include an aligning member 37 having an end face in the first right-angled direction facing the other of the first normal direction and the normal line of the surface in the first right-angled direction. Illustratively, the alignment member 37 may be provided at the other end of the linear portion 31. For example, when the cross section of the outer surface of the other end of the linear portion 31 is circular, the outer surface of the linear portion 31 may be formed as a curved surface. In this case, the other end of the linear portion 31 whose outer surface is curved by the aligning member 37 can be stably supported on the wall surface facing the wall surface on which the one end of the sheet member 2 is supported.

2, the connection between the connection housing block 311, the base housing block 312 and the expansion housing block 313 may be a screw connection. Thus, the length of the housing 3 can be more easily adjusted (extended length). In addition, when the housing 3 is extended in a threaded manner between circular cross sections, the connection between the bar members can be considered as a connection by a magnetic force and a connection by a wedge connection as described above. That is, a portion of the linear portion 31 (including a portion where the connection between the base housing block 312, the connection housing block 311 and the expansion housing block 313 is made) The outer surface has a circular cross-section, and the base housing block 312 can be connected to the connection housing block 311 or the expansion housing block 313 through a screw connection. One end of the base bar member 12 may be connected to the other end of the connecting bar member 11 or the other end of the extending bar member 13. [ As such, the threaded engagement of the housing blocks can be implemented to be operatively associated with the engagement between the bar members. However, since the threaded connection between the circular cross sections is progressively performed by rotation, in the case of the wedge connection, it is preferable that the male and female wedge shapes shown in FIG. 10 are provided such that their cross sections are circular.

Conventionally, when measuring the interval between bridge superstructures, the user has to directly approach the bridge superstructure and directly measure the interval, thereby posing a risk of safety accidents, and the user's convenience is not considered. For example, if you want to measure the spacing between girders, you have to measure directly up to the pier and you can not measure the gap corresponding to the deep space in the space between the girder and the girder, even if you go up the pier. In addition, even when it is desired to measure the distance between the girder and the shift, the user has to measure directly on the alternate bearing surface.

However, according to the present gap measuring apparatus, it is possible to measure the gap with respect to the first orthogonal direction orthogonal to the longitudinal direction by advancing the bar member 1 in the longitudinal direction, and the structure is also formed in the form of a cantilever Since the protruding protruding structure is provided with simplicity, the interval measurement can be performed safely, easily, and accurately. According to the gap measuring apparatus, even if the user does not directly ascend to the bridge pier or the alternation, the interval of the bridge superstructure can be measured on the track observer by using the long extension length of the distance measuring apparatus. According to this gap measuring apparatus, since the insertion length of the housing 3 can be measured, it is possible to grasp the position where the interval measurement is performed. Therefore, the gap is measured for each girder (or slab) in the lateral direction or the square direction Therefore, the safety diagnosis can be made more systematically. In addition, since the gap measuring apparatus has a simple structure, it can be easily handled, manufactured and repaired.

It will be understood by those of ordinary skill in the art that the foregoing description of the embodiments is for illustrative purposes and that those skilled in the art can easily modify the invention without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be interpreted as being included in the scope of the present invention.

1: bar member
11: Connection bar member
12: base bar member
13: Extension bar member
2: sheet member
21: end member
25:
3: Housing
3a: longitudinal directional level
3b: the first perpendicular direction horizontal scale
31:
311: Connection housing block
312: base housing block
313: Extended housing block
32:
33: end hole
34: Hinge coupling
38:
39: Insertion length indicator
37: Alignment member
4: Driving force transmitting unit
41: Linear driving force transmitting portion
42: Reference member
43: Handle
421: Second graduation scale
5: member guide portion
51: Bunch
500: bridge superstructure

Claims (15)

An apparatus for measuring the distance between two bridge superstructures (500) or alternating with a bridge superstructure (500) for safety diagnosis,
A bar member (1);
A sheet member (2) whose other end is connected to one end of the bar member (1);
The bar member (1) arranged to extend along the longitudinal direction is movably guided along the longitudinal direction, and extends along the longitudinal direction so as to be bent and extended in one direction out of a first right angle direction orthogonal to the longitudinal direction A housing (3) including a member guide portion (5) for movably guiding the arranged sheet member (2) along the longitudinal direction and the first right angle direction; And
And a driving force transmitting unit (4) for transmitting a driving force for moving the bar member (1) along the longitudinal direction to the bar member (1)
The sheet member (2) is selectively bendable in the first bending direction only in a first bending direction bent in one direction out of the first perpendicular direction in the longitudinal direction, only when a bending moment acts at a reference bending moment or more , A bending moment that is equal to or greater than the reference bending moment,
The member guide portion 5 applies a bending moment exceeding the reference bending moment to the sheet member 2 so that a part of the sheet member 2 is bent in one direction out of the first right angle direction in the longitudinal direction, And a curved portion (51)
The housing 3 includes a linear portion 31 in which the bar member 1 and a portion of the sheet member 2 facing the longitudinal direction are located, And a bent portion (32) on which the facing portion is located,
The driving force transmitting unit 4 is inserted into the linear portion 31 from the other end side of the linear portion 31 and connected to the other end of the bar member 1, And a linear driving force transmitting portion (41) moving along the longitudinal direction according to a screwing amount by relative rotation with respect to the linear portion (31)
The linear portion 31 includes a connection housing block 311 connected to the bent portion 32 and a base housing block 312 directly or indirectly connected to the other end of the connection housing block 311,
One or more expansion housing blocks 313 can be disposed between the connection housing block 311 and the base housing block 312,
The bar member 1 includes a connecting bar member 11 at least partially disposed inside the connecting housing block 311 and having one end connected to the other end of the sheet member 2, And a base bar member (12) at least partially disposed inside and having one end directly or indirectly connected to the other end of the connecting bar member (11)
The driving force transmitting unit 4 is mounted on the base housing block 312 to transmit a driving force for moving the base bar member 12 along the longitudinal direction to the base bar member 12,
When the expansion housing block 313 is disposed, the other end of the expansion housing block 313 is connected to one end of the base bar member 12, and one end of the expansion housing block 313 is connected to the other end of the connection bar member 11 At least a part of the extension bar member 13 to be connected is arranged,
The linear driving force transmitting portion 41 is provided to be rotatable with respect to a shaft extending from the bar member 1 in the other direction so that the rotational force of the linear driving force transmitting portion 41 is transmitted to the bar member 1 ), Which is a connection type measuring device capable of measuring the interval of the bridge superstructure using the helical method in the safety diagnosis. The method according to claim 1,
On the outer surface of the linear portion 31, a first graduation scale 38 is formed along the longitudinal direction,
The driving force transmitting unit 4 includes a reference member 42 connected to the linear driving force transmitting portion 41 and moved along the longitudinal direction in conjunction with the movement of the linear driving force transmitting portion 41,
The folded portion 32 of the housing 3 is formed such that when the bar member 1 is moved along one direction of the longitudinal direction, a part of the sheet member 2 is bent in a direction of the cantilever And an end hole (33) through which the sheet member (2) passes in one direction out of the first right angle direction so as to protrude in a first direction,
The reference member 42 has a length in the cantilever portion protruding out of the sheet member 2 in the first graduation system 38 and a length in which the length of the housing 3 with respect to the first right angle direction is taken into account Wherein the height of the bridge structure is measured by a spiral method during a safety diagnosis. 3. The method of claim 2,
The reference member 42 is formed so as to surround the outer surface of the linear portion 31 along the circumferential direction,
On the outer surface of the reference member 42, a second graduation scale 421 is formed along the circumferential direction,
Wherein the second scale system (421) has a smaller unit than the unit of the first scale system (38). 3. The method of claim 2,
The width of the sheet member (2) in the second perpendicular direction perpendicular to the longitudinal direction and the first right angle direction is larger than the width of the first (3) A cross section of a curved sheet shape having an intermediate portion larger than a thickness in a direction perpendicular to the first direction and being convex in the other direction among the first direction,
The curvature of the sheet member (2) in the curved portion (51) is greater than that of the curved sheet-shaped curved surface convex in one direction among the first right angle direction, Wherein a curvature of a portion of the bridge structure is easily guided. 5. The method of claim 4,
The longitudinal direction of the housing 3 corresponds to a lateral direction or a skew direction of the bridge upper structure 500 and the first perpendicular direction corresponds to the longitudinal direction of the bridge upper structure 500 Direction or a horizontal direction orthogonal to the square direction, the second right angle direction corresponds to the vertical direction,
Wherein the sheet member (2) has an end member (21) at one end of which a normal line of the surface is formed with an end surface facing one direction of the first perpendicular direction,
The cross section of the sheet member 2 is formed in such a manner that when the cantilever portion including the end member 21 protrudes to the maximum from the end hole 33, Wherein the cantilever portion protruding to the maximum is not twisted and deformed. 6. The method of claim 5,
Wherein the length of the cantilever portion protruding to the maximum is set to a length of 50 cm or less, which is a measurable length of the interval of a general bridge excluding a long bridge, and a connection type measurement capable of measuring the interval of the bridge superstructure using a helical method Device. 6. The method of claim 5,
The cross section of the sheet member 2 is formed so that when the cantilever portion including the end member 21 protrudes to the maximum from the end hole 33, And the reference bending moment is larger than the maximum bending moment that can be obtained by the spiral method. 6. The method of claim 5,
The bent portion 32 is formed in the linear portion 31 so that the curved portion of the sheet member 2 can be extended so that the portion of the sheet member 2 facing the first perpendicular direction faces the longitudinal direction. Is capable of rotating about the second right angle direction with respect to the axis of the bridge. 6. The method of claim 5,
On the outer surface of the housing 3, an insertion length indicating portion 39 is formed to indicate the length of the housing 3 inserted between the two bridge superstructures 500 or alternately with the bridge superstructure 500 A connection type measuring device capable of measuring the interval of the bridge superstructure using the helical method in the safety diagnosis. delete 6. The method of claim 5,
One end of the base bar member 12 is connected to the other end of the connecting bar member 11 or the other end of the extending bar member 13 by a magnetic force or a wedge-
Wherein the magnitude of the magnetic force or the wedge connection is set larger than the magnitude of the driving force so that the movement of the base bar member (12) can be interlocked with the connecting bar member (11) or the extending bar member (13) Connection type measuring device capable of measuring the interval of bridge superstructure using helical method for safety diagnosis. 12. The method of claim 11,
The base housing block 312 is connected to the connection housing block 311 or the expansion housing block 313 through a screw connection,
Wherein one end of the base bar member (12) is connected to the other end of the connection bar member (11) or the other end of the extension bar member (13) Connectable measuring device that can measure. 6. The method of claim 5,
The base bar member 12 is disposed movably along the longitudinal direction within a range in which at least a part of the base bar member 12 remains inside the base housing block 312,
The extension bar member 13 is disposed movably along the longitudinal direction within a range where at least a part remains within the expansion housing block 313,
The connection bar member 11 is disposed movably along the longitudinal direction within a range where at least a part of the connection bar member 11 remains inside the connection housing block 311,
The base bar member 12, the extension bar member 13, and the connecting bar member 11 are movable in a direction corresponding to the length of the cantilever portion protruding to the maximum, Wherein the length of the bridge structure is longer than the length of the bridge structure.
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