KR102537674B1 - Edge Distance Measuring Device for Bridge Safety Inspection - Google Patents

Abstract

The present invention relates to an edge distance measuring device for a bridge safety diagnosis, which comprises: a holder fixing plate (30) having a predetermined thickness; a shaft (31) which is formed at the holder fixing plate (30); a male screw unit (32) which is formed at the shaft (31); a left side height adjustment arm (40) and a right side height adjustment arm (50) which cross with each other in an inverted V shape; a horizontal bar (60) which is supported with the upper surface (21) of a bridge lower structure (20), and is installed at the left side height adjustment arm (40) and the right side height adjustment arm (50); a front i-ring (41) which is formed at the upper end of the left side height adjustment arm (40); a rear i-ring (51) which is formed at the upper end of the right side height adjustment arm (50); a ring spacer (70) which is rotated along with the rear i-ring (51); a plunger screw hole (71) which is formed at the ring spacer (70); a plunger bolt (74) which is installed at the plunger screw hole (71); a steel ball (73) which receives elastic force in a protruding direction toward the front i-ring (41) by a spring (72) built in the plunger bolt (74); a stopping groove (41g) which determines the location of the steel ball (73); a pressure adjustment nut (80) which is coupled to the male screw unit (32); a spring storage chamber (81) which is formed at the pressure adjustment nut (80); a friction spring (82) which resists between the rear i-ring (51) and the pressure adjustment nut (80); and a laser holder (90) which holds the laser distance measuring device (22). Therefore, the edge distance of a bridge may be conveniently and precisely measured.

Description

Edge Distance Measuring Device for Bridge Safety Inspection}

The present invention relates to a device for measuring edge distance for diagnosing bridge safety, and more particularly, for diagnosing safety for bridges, which sets a reference position using the corner of a bridge substructure and conveniently measures edge distance using a laser distance meter. It relates to edge distance measuring devices.

In general, bridge bearings are made of rubber bearings or steel bearings. When measuring the edge distance, it is obtained by measuring the distance from the center of the anchor bolt fixing the bridge bearing to the edge of the bridge substructure (pier, abutment, etc.) .

1 is a view schematically showing the measurement of the edge distance using a tape measure, and as shown therein, the anchor bolt fixing the bridge support 13 to the end of the steel band 11 drawn out from the tape measure 10 ( 12) is read from the steel band 11 to measure the scale vertically aligned with the podium 17 of the bridge substructure 15 in the state of being located at the center.

However, since the edge distance measurement using such a tape measure requires the naked eye to find and read a scale that matches the edge 17 of the lower structure 15, there is a problem in that a large measurement error occurs.

In addition, as the length of the steel band 11 drawn from the tape measure 10 increases, the deflection of the steel band 11 increases. This deflection of the steel band 11 causes a problem of increasing measurement error. In addition, accurate measurement is possible only when the tape measure 10 is not shaken, but there is a problem in that the tape measure 10 shakes due to shaking of the hand.

In order to improve these problems, Korean Patent Publication No. 10-2018-0135765 (hereinafter referred to as 'Prior Art 1') proposes to install a L-shaped edge support at the corner of the bridge substructure. In the prior art 1, the edge distance is measured by drawing a steel band from the tape measure installed inside the tape measure mounting unit to the center of the anchor bolt fixing the bridge support.

However, prior art 1 still has a problem of low measurement accuracy due to sagging of the steel band because it uses a tape measure, and since the height cannot be adjusted, it is necessary to prepare several copies of different dimensions according to the height of the anchor bolt. There was an inconvenience.

In Korean Patent Registration No. 10-1112180 (hereinafter referred to as 'Prior Art 2'), it is proposed to measure the edge distance by attaching a movable measurer sliding in a straight direction to the edge of a bridge substructure.

However, prior art 2 has a problem in that it is very inconvenient to use and reduces the concentration and precision of the measurement work by increasing fatigue accumulation because the handle part must be continuously pressed against the edge surface of the lower structure to maintain the adjusted height.

Korean Patent Registration No. 10-1876546 (hereinafter referred to as 'Prior Art 3') discloses an optical method using a laser optical distance meter installed in the measuring unit in a state where the L-shaped vertical part and the measuring part are closely attached to the edge of the bridge substructure. It has been proposed to measure the edge distance with

However, in the prior art 3, since the vertical part must be continuously pressed against the edge surface of the lower structure to maintain the adjusted height, it is very inconvenient to use and increases fatigue accumulation, thereby reducing the concentration and precision of the measurement work.

Domestic Patent Publication No. 10-2018-0135765 (published on 2018.12.21.) Korean Registered Patent Publication No. 10-1112180 (Announcement Date 2012.03.13.) Korean Registered Patent Publication No. 10-1876546 (Announcement date 2018.08.09.)

The present invention has been made to solve the above problems, and its object is to provide a edge distance measuring device for bridge safety diagnosis that can conveniently and precisely measure the edge distance of a bridge.

In order to achieve the object of the present invention, the edge distance measuring device for bridge safety diagnosis includes a holder fixing plate having a constant thickness; A shaft formed in the front center of the holder fixing plate; A male thread formed at the center of the end of the shaft; a left height control arm and a right height control arm that are spaced apart from each other in the front and rear directions and meet in a reverse V shape; Horizontal bars supported on the upper surface of the bridge substructure and installed on the left height control arm and the right height control arm, respectively; A flat donut-shaped front eye ring formed on the upper end of the left height adjusting arm to be supported on the outer circumferential surface of the shaft and closely attached to the front of the holder fixing plate; Formed at the top of the right height adjusting arm, concentric with the front eyering and spaced apart at regular intervals, a flat donut-shaped rear eyering; A ring spacer supported on an outer circumferential surface of the shaft between the front and rear eye-rings and rotated together with the rear eye-ring; A plunger screw hole formed eccentrically from the center of the ring spacer; A plunger bolt installed in the plunger screw hole; A steel ball receiving an elastic force in a protruding direction toward the front eye ring by a spring embedded in the plunger bolt; Stop grooves arranged in a circular shape on one side of the front i-ring at an equal angle to each other and determining the position of the steel ball; A pressure adjusting nut coupled to the male threaded portion; A spring storage chamber formed at a constant depth in the center of one side end of the pressure adjusting nut; a friction spring located in the spring storage chamber so that the male screw portion passes through the center and repelled between the rear eye ring and the pressure adjusting nut; It is installed on the holder fixing plate and has a feature including a laser holder that bites or releases the bite of the laser range finder.

The laser holder has a distance measurement reference surface in close contact with the end of the laser distance meter, and a reference block installed on the rear surface of the holder fixing plate; A support plate formed horizontally on the reference block and supporting a lower surface of the laser range finder; A fixing tank installed vertically on the left side of the support plate and in close contact with the left side of the laser distance meter; A pair of guide holes penetrating the left and right side surfaces of the support plate in a horizontal direction; A pair of slide shafts inserted into the guide hole and moving in left and right directions; A movable jaw coupled to the right end of the slide shaft and pressing the right side of the laser distance meter; A slide shaft passes through the center, and a spring that rebounds between the support plate and the movable jaw; Screw holes penetrating the support plate from side to side; An idle hole formed in the movable tank so that the center coincides with the screw hole; A transfer screw coupled to the screw hole through the idle hole; It is installed at the right end of the transfer screw and has a feature including a stop knob for stopping the movable jaw by resisting the extension of the ablation spring.

The present invention is a fastening hole formed in series while achieving a constant interval along the longitudinal direction of the left height control arm and the right height control arm; A step spacer located between the edge of the lower structure and the left height control arm; A long spacer positioned between the end surface of the lower structure and the right height control arm; tap holes respectively formed at the centers of the short-spaced material and the long-spaced material; A fixing screw coupled to the tapped hole through a fastening hole; the length of the spacer is equal to the sum of the thickness of the holder fixing plate and the thickness of the reference block, and the length of the spacer is equal to the thickness of the front eyering It is characterized by being formed with the same length as the sum of the thicknesses of the ring spacer plus the length of the spacer.

The present invention is an extension bar connected in the longitudinal direction to the front end of the horizontal bar; circular center holes each formed at a constant depth at the center of the front end of the horizontal bar and the extension bar; a female screw hole formed at the inner center of the center hole and having a smaller inner diameter than the center hole; an annular protrusion formed at the rear end of the extension bar and inserted into the center hole; It is formed at the center of the end of the annular protrusion and is characterized by including a stud bolt coupled to the female screw hole.

As described above, the present invention is configured to freely adjust the height of the laser range finder 22 using the left height control arm 40 and the right height control arm 50, so that the laser range finder 22 There is an effect of quickly and conveniently adjusting the height of the output laser beam (B) according to the height of the anchor bolt (25).

When the laser distance meter 22 and the laser holder 90 are rotated, the laser beam B output from the laser distance meter 22 is rotated eccentrically about the center of rotation of the shaft 31, so that the laser When matching the beam (B) to the height of the anchor bolt 25, there is an effect of finely adjusting the height.

After adjusting the height of the laser distance meter 22 and the laser beam B, turn the pressure adjusting nut 80 and close it to the rear eye ring 51, the left height adjusting arm 40 and the right height adjusting arm 50 There is an effect of stopping the rotation of the laser distance meter 22 and the laser holder 90 as well as being able to stop the rotation.

In the process of adjusting the angle of the left height adjusting arm 40 and the right height adjusting arm 50, the steel ball 73 provided in the plunger bolt 74 installed in the ring spacer 70 is attached to the rear eye ring 51. Since it is configured to be intermittently caught in the formed stop groove 41g, it is possible to conveniently position the left height control arm 40 and the right height control arm 50 and continuously maintain the determined position. there is

There is an effect of freely changing the vertical position of the horizontal bar 60 by using the fastening holes 40h and 50h formed along the longitudinal direction of the left height-adjusting arm 40 and the right height-adjusting arm 50. .

There is an effect of preventing the extension bar 300 connected to the horizontal bar 60 from being conducted forward.

Since the frictional force is applied between the front eye ring 41 and the ring spacer 70 using the elastic restoring force acting from the friction spring 82, the natural height control arm 40 and the right height control arm 50 There is an effect of preventing rotation or sagging, and there is an effect of obtaining smooth movement when adjusting the angles of the left height adjustment arm 40 and the right height adjustment arm 50.

Since the frictional force is applied between the front eyering 41 and the holder fixing plate 30 using the elastic restoring force acting from the friction spring 82, the natural rotation of the laser holder 90 can be prevented. , When rotating the laser holder 90 and the laser range finder 22, there is an effect of enabling smooth rotation.

When the stop knob 98 provided in the laser holder 90 is rotated clockwise or counterclockwise, the distance between the fixed jaw 93 and the movable jaw 95 can be narrowed or widened, so the laser distance meter 22 ) to the laser holder 90 to fix or separate it.

Since the short spacer 100 installed on the left height control arm 40 and the long spacer 200 installed on the right height control arm 50 are configured to contact the end surface 23, the laser distance meter 22 There is an effect of matching the distance measurement reference surface 91a of the reference block 91 closely to the end 22e of the end surface 23 with the end surface 23.

The length L1 of the short spacer 100 and the length L2 of the long spacer 200 are formed differently, and the thickness of the holder fixing plate 30 and the reference block 91 and the front eye ring 41 Since it is configured to have lengths L1 and L2 corresponding to the thickness of the ring spacer 70 , it is convenient to position the laser beam B at right angles to the end face 23 .

Since the pressure adjusting nut 80 is rotated forward and backward to adjust the distance between the rear eye ring 51 and the pressure adjusting nut 80, the effect of continuously adjusting the pressure applied from the friction spring 82 there is

Since the left height adjustment arm 40 and the right height adjustment arm 50 can be staggered with each other by the ring spacer 70 located between the front eye ring 41 and the rear eye ring 51, the left height adjustment arm In the process of rotating the (40) and the right height control arm (50), there is an effect of preventing interference with each other.

Since the annular protrusion 301 formed on the extension bar 300 is inserted into the center holes 61 and 303 formed at the ends of the horizontal bar 60 and the extension bar 300, the horizontal bar 60 and the extension Not only can the centers of the bars 300 be conveniently and precisely aligned, but also the centers of the extension bars 300 and other extension bars 300 can be conveniently and precisely aligned.

1 is a view schematically showing the measurement of the edge distance of a bridge using a conventional tape measure
2 is an exploded perspective view according to the present invention
Figure 3 is an exploded perspective view of Figure 2 viewed from the opposite side
4 is an exploded perspective view showing an enlarged front eyering, a ring spacer, a rear eyering, a plunger bolt, and peripheral components thereof according to the present invention;
Figure 5 is an exploded perspective view of Figure 4 viewed from the other side
Figure 6 is an exploded perspective view showing a laser holder according to the present invention
Figure 7 is an exploded perspective view of Figure 6 viewed from the other side
Figure 8 is a perspective view showing that the present invention is installed at the corner of the bridge substructure to measure the edge distance
Figure 9 is a perspective view of Figure 8 viewed from the other side
10 is a bottom perspective view according to the present invention
11 is a front view according to the present invention, showing that the laser distance meter is raised by narrowing the gap between the left height control arm and the right height control arm.
12 is a front view according to the present invention, showing that the laser distance meter is lowered by widening the distance between the left height control arm and the right height control arm.
13 is a plan view according to the present invention
14 is a side cross-sectional view according to the present invention
15 is a partially enlarged plan cross-sectional view according to the present invention, in which the angle of the left height adjusting arm and the right height adjusting arm can be adjusted by retracting the pressure adjusting nut, and the height of the laser beam can be finely adjusted using the eccentric rotation of the laser holder. A drawing showing a state that can be adjusted
16 is a partially enlarged plan cross-sectional view according to the present invention, showing that the rotation of the left height adjusting arm, the right height adjusting arm, and the laser holder is stopped by moving the pressure adjusting nut forward.
Figure 17 is a side cross-sectional view of Figure 15
18 is a view schematically showing measuring the edge distance of a bridge using the present invention

Hereinafter, an embodiment according to the present invention will be described in detail with reference to FIGS. 2 to 18 of the accompanying drawings.

The present invention is a holder fixing plate 30 having a constant thickness; A shaft 31 formed in the front center of the holder fixing plate 30; A male screw portion 32 formed at the center of the end of the shaft 31 is included.

The holder fixing plate 30 can be formed in a disk shape, for example. The holder fixing plate 30, the shaft 31, and the male screw portion 32 can be molded integrally by turning metal or reinforced plastic as a material, and are all molded to form a straight line on the coaxial line.

15 to 17, when the diameter of the male screw portion 32 is smaller than the diameter of the shaft 31, when assembling the front eye ring 41 and the ring spacer 70 to the shaft 31 It is possible to prevent the front eye-ring 41, the ring spacer 70, and the rear eye-ring 51 from interfering with the male screw portion 32.

The present invention comprises a left height control arm 40 and a right height control arm 50 that are spaced apart from each other in the front and rear directions and meet staggeredly in an inverted V shape; It is supported on the upper surface 21 of the bridge substructure 20 and includes a horizontal bar 60 installed on the left height control arm 40 and the right height control arm 50, respectively.

The left height control arm 40 and the right height control arm 50 may be formed in the form of a straight flat bar having a predetermined thickness and width using metal as a material. The left height control arm 40 and the right height control arm 50 also serve as handles when adjusting the height of the laser distance meter 22.

That is, the height of the laser distance meter 22 can be adjusted by holding the left height control arm 40 with the left hand and moving the right height control arm 50, and holding the right height control arm 50 with the right hand and moving the left height control arm The height of the laser distance meter 22 can be adjusted by moving 40.

The horizontal bar 60 is installed to form a right angle in the horizontal direction from the rear of the left height control arm 40 and the right height control arm 50, and the horizontal bar 60 is made of a metal round bar or plastic round bar and has a constant diameter and can be molded to have a length.

After forming a tapped hole 60t for bar fastening at the center of the rear end of the horizontal bar 60, the horizontal bar 60 is aligned so that the centers of the tapped hole 60t and the fastening holes 40h and 50h coincide. When the bar fixing bolt 63 is coupled to the bar fastening tap hole 60t through the fastening holes 40h and 50h in a state of being in close contact with the rear surfaces of the left height adjusting arm 40 and the right height adjusting arm 50 , The horizontal bar 60 is fixed to the left height control arm 40 and the right height control arm 50, respectively.

The present invention is formed on the upper end of the left height adjustment arm 40 so as to be supported on the outer circumferential surface of the shaft 31, and a flat donut-shaped front eye ring 41 in close contact with the front of the holder fixing plate 30; Formed on the upper end of the right height adjusting arm 50, concentric with the front eye-ring 41 and a flat donut-shaped rear eye-ring 51 spaced apart at regular intervals; A ring spacer 70 supported on the outer circumferential surface of the shaft 31 between the front eye-ring 41 and the rear eye-ring 51 and rotated together with the rear eye-ring 51 is included.

The front eye ring 41 may be formed in the form of a circular ring having a constant thickness at the upper end of the left height adjusting arm 40 . The rear eye ring 51 may be formed in the form of a circular ring having a constant thickness at the upper end of the right height adjusting arm 50 .

In the center of the front eye-ring 41 and the rear eye-ring 51, circular holes 41h and 51h each having an inner diameter corresponding to the outer diameter of the shaft 31 are bored.

The ring spacer 70 is for maintaining a constant distance between the front eye-ring 41 and the rear eye-ring 51, and can be molded into a disk shape having a certain thickness by turning metal or reinforced plastic as a material. .

The coupling of the ring spacer 70 and the rear eye ring 51 is formed such that, for example, a plurality of tap holes 51 t are arranged in a circular shape in the rear eye ring 51, and the ring spacer 70 has a tap hole 51 t When a counterbore hole 70c is formed where the center coincides with and then the ring fixing bolt 75 is coupled to the tapped hole 51t through the counterbore hole 70c, the ring spacer 70 and the rear eye ring 51 ) can be combined.

That is, the ring spacer 70 and the rear eye ring 51 are rotated together in a coupled state, and the ring spacer 70 and the front eye ring 41 rotate in opposite directions in a state of being in close contact with each other while sliding or left by frictional force. It serves to maintain the angle between the height adjusting arm 40 and the right height adjusting arm 50.

A through hole 76 having an inner diameter corresponding to the outer diameter of the shaft 31 is drilled in the center of the ring spacer 70 so that the ring spacer 70 can rotate while being supported on the outer circumferential surface of the shaft 31 .

The present invention includes a plunger screw hole 71 formed eccentrically from the center of the ring spacer 70; A plunger bolt 74 installed in the plunger screw hole 71; A steel ball 73 receiving elastic force in a protruding direction toward the front eye ring 41 by the spring 72 embedded in the plunger bolt 74; It is arranged in a circle on one side of the front eye ring 41 while forming an equal angle to each other, and includes a stop groove 41g for determining the position of the steel ball 73.

As shown in the enlarged view of FIG. 17, in the plunger bolt 74, the steel ball 73 is subjected to an elastic force in the direction of protruding outward by the built-in spring 72, and the hole formed in the center of the plunger bolt 74 The outer edge is formed in a conical shape toward the center to have an inner diameter smaller than the diameter of the steel ball 73 to prevent the steel ball 73 from coming off.

The steel ball 73 has a spherical shape, which is round like a ball, and is molded from a metal having high hardness such as bearing steel. The stop groove 41g may be formed in a hemispherical shape, for example, and in this case, it may be formed to have an inner diameter corresponding to the outer diameter of the steel ball 73.

The present invention includes a pressure adjusting nut 80 coupled to the male threaded portion 32; A spring storage chamber 81 formed at a constant depth at the center of one side end of the pressure adjusting nut 80; a friction spring 82 positioned in the spring storage chamber 81 so that the male screw portion 32 passes through the center and repelled between the rear eye ring 51 and the pressure adjusting nut 80; It is installed on the holder fixing plate 30, and includes a laser holder 90 that bites or releases the bite of the laser distance meter 22.

A screw hole 80t coupled to the male screw portion 32 is formed at the center of the pressure adjusting nut 80 . The spring storage chamber 81 may be formed as a bottomed circular hole having a constant depth and inner diameter.

The friction spring 82 may be composed of a compression coil spring made by spirally winding a spring steel wire.

The laser holder 90 according to the present invention has a distance measurement reference surface 91a in close contact with the end 22e of the laser distance meter 22, and is installed on the rear surface of the holder fixing plate 30 Reference block 91; It is formed horizontally on the reference block 91 and includes a support plate 92 supporting the lower surface of the laser distance meter 22.

In general, the laser distance meter 22 can measure only the length of the body of the laser distance meter 22 or more, and the measurement reference position of the laser distance meter 22 corresponding to the distance "0" is of the reference block 91. It is the end 22e of the laser rangefinder 22 that contacts the ranging reference plane 91a.

The reference block 91 and the support plate 92 may be integrally molded using metal or plastic as a material.

The configuration for fixing the reference block 91 to the holder fixing plate 30 is, for example, forming a block fixing tap hole 30t in the holder fixing plate 30, and a block fixing tap hole in the reference block 91. After forming a block fastening hole (91h) whose center coincides with (30t), when the block fastening bolt (91b) is coupled to the block fastening hole (91h) through the block fastening hole (91h), the reference block 91 is the holder. It is fixed to the fixing plate 30.

The laser holder 90 according to the present invention is installed vertically on the left side of the base plate 92, and the fixed jaw 93 in close contact with the left side of the laser distance meter 22; a pair of guide holes 92h penetrating the left and right side surfaces of the support plate 92 in the horizontal direction; a pair of slide shafts 94 that are inserted into the guide holes 92h and move in the left and right directions; It is coupled to the right end of the slide shaft 94 and includes a movable jaw 95 that presses the right side of the laser distance meter 22.

The fixed tank 93 and the movable tank 95 can be molded, for example, from a rectangular metal plate having a constant thickness. Rubber pads 99 are attached to the contact surfaces of the fixed jaw 93 and the movable jaw 95, which are in close contact with the left and right sides of the laser distance meter 22, to reduce surface damage of the laser distance meter 22. can

As shown in FIG. 13, the laser beam B output from the laser distance meter 22 has an eccentric rotation radius E that is a certain distance away from the rotation center of the shaft 31. By rotating the laser distance meter 22 and the laser holder 90 around the shaft 31, the height of the laser beam B can be finely adjusted.

The configuration for fixing the fixing jaw 93 to the support plate 92 is, for example, forming a tab hole 92t for fixing the jaw on the left side of the support plate 92, and a tap hole for fixing the jaw in the fixing jaw 93 ( 92t) and the center fastening hole (93h) are drilled, and then, when the jaw fixing screw (93b) is coupled to the jaw fixing tapped hole (92t) through the fastening hole (93h), the fixing jaw (93) is 92) is fixed.

In order to prevent the end of the slide shaft 94 from interfering with the fixed jaw 93 when the slide shaft 94 moves in the axial direction, an inner diameter that is coincident with the center of the slide shaft 94 and larger than the slide shaft 94 An anti-interference hole 93d may be formed in the fixing tank 93.

In order to prevent the end of the conveying screw 97 from interfering with the fixing tank 93 when the conveying screw 97 moves in the axial direction, an inner diameter that is coincident with the center of the conveying screw 97 and larger than that of the conveying screw 97 A screw passage hole 93f having can be formed in the fixing tank 93.

To connect the movable jaw 95 and the slide shaft 94, for example, a tap hole 94t for shaft fixation is formed at the center of the end of the slide shaft 94, and a tap hole for shaft fixation is formed in the movable jaw 95. After drilling the shaft fastening hole 95a whose center coincides with the shaft fastening hole 95a, when the shaft fastening bolt 95b is coupled to the shaft fastening tapped hole 94t through the shaft fastening hole 95a, the movable jaw 95 It is coupled to the end of the slide shaft 94.

The pair of guide holes 92h are formed parallel to each other, and the inner diameter of the guide hole 92h is formed corresponding to the outer diameter of the slide shaft 94.

The slide shaft 94 can be made of a straight metal round bar having a constant diameter and length, and the outer circumferential surface of the slide shaft 94 can be polished or plated. The outer diameter of the slide shaft 94 is made smaller than the inner diameter of the guide hole 92h so that the slide shaft 94 moves smoothly along the guide hole 92h.

The laser holder 90 according to the present invention, the slide shaft 94 is passed through the center, the bulim spring 96 that rebounds between the support plate 92 and the movable jaw 95; screw holes 92s penetrating the support plate 92 from side to side; an idle hole 95h formed in the movable tank 95 so as to coincide with the center of the screw hole 92s; A transfer screw 97 coupled to the screw hole 92s through the idle hole 95h; It is installed at the right end of the transfer screw 97, and includes a stop knob 98 for stopping the movable jaw 95 by resisting the extension of the ablation spring 96.

The bulim spring 96 may be composed of a compression coil spring made by spirally winding a spring steel wire. The screw hole 92s may be formed parallel to the guide hole 92h, and the inner diameter of the idle hole 95h may be larger than the outer diameter of the transfer screw 97.

The transfer screw 97 and the stop knob 98 may be integrally formed by turning a metal round bar as a material. A cylindrical hub 98p having an outer diameter larger than the inner diameter of the idle hole 95h and a smaller outer diameter than the stop knob 98 may be formed at the center of one side of the stop knob 98 .

The present invention includes fastening holes 40h and 50h formed in series at regular intervals along the longitudinal direction of the left height control arm 40 and the right height control arm 50; Step spacer 100 positioned between the end surface 23 of the lower structure 20 and the left height control arm 40; a long spacer 200 positioned between the end surface 23 of the lower structure 20 and the right height adjusting arm 50; Tap holes 100t and 200t formed at the centers of the short spacer 100 and the long spacer 200, respectively; It includes fixing screws 102 and 202 coupled to the tapped holes 100t and 200t through the fastening holes 40h and 50h.

The short spacer 100 and the long spacer 200 may be molded into a round bar shape having a constant diameter and length using metal or plastic as a material.

In the present invention, the length L1 of the spacer 100 is formed to the same length as the sum of the thickness T2 of the holder fixing plate 30 and the thickness T1 of the reference block 91, and the long spacer ( The length L2 of 200) is equal to the sum of the thickness T3 of the front eye ring 41 and the thickness T4 of the ring spacer 70 plus the length L1 of the spacer 100. form with

As shown in the accompanying drawings FIGS. 13 to 16, the reason why the length L1 of the short spacer 100 and the length L2 of the long spacer 200 are formed differently from each other is from the laser distance meter 22 This is to make the laser beam (B) output and directed toward the anchor bolt 25 installed on the bridge bearing 26 form a right angle with the end surface 23.

The present invention is an extension bar 300 connected in the longitudinal direction to the front end of the horizontal bar 60; Circular center holes 61 and 303 each formed at a predetermined depth at the center of the front end of the horizontal bar 60 and the extension bar 300; It is formed at the inner center of the center hole 61 (303) and includes a female screw hole 62 (304) having a smaller inner diameter than the center hole (61) (303).

The extension bar 300 may be molded to have a constant diameter and length by using a metal round bar or a plastic round bar as a material.

The present invention is formed at the rear end of the extension bar 300, the annular protrusion 301 is inserted into the center hole (61) (303); It is formed at the center of the end of the annular protrusion 301 and includes a stud bolt 302 coupled to the female screw holes 62 and 304.

The center of the horizontal bar 60 and the extension bar 300 can be aligned with each other by the annular protrusion 301 inserted into the center hole 61 (303), and another extension bar 300 can be connected to the extension bar 300. ) can also be centered.

In the drawing, reference numeral 24 denotes a chamfered edge of the lower structure 20, 27 denotes the upper part of the bridge, and 28 denotes the supporting concrete supporting the bridge support 26.

The operation according to the present invention will be described in detail below.

Assuming that the transfer screw 97 is a right-handed screw and explaining the process of installing the laser distance meter 22 to the laser holder 90, the transfer screw 97 is rotated counterclockwise using the stop knob 98 When rotated, the hub 98p formed on the stop knob 98 moves away from the movable jaw 95.

At this time, since the movable jaw 95 always receives elastic force in the direction away from the fixed jaw 93 by the ablation spring 96, the movable jaw 95 is fixed while moving along the hub 98p by the ablation spring 96. The gap between the jaw 93 and the movable jaw 95 widens.

At this time, since the slide shaft 94 is connected to the movable jaw 95, when the movable jaw 95 moves, the slide shaft 94 moves together with the movable jaw 95, and the slide shaft 94 has a guide hole ( 92h) will receive straight-line guidance.

In this way, while the laser distance meter 22 is placed on the base plate 92 in a state where the distance between the fixed jaw 93 and the movable jaw 95 is wider than the width of the laser distance meter 22, the laser distance meter 22 The end 22e of the is brought into close contact with the distance measuring reference plane 91a formed on the reference block 91, and the left side of the laser distance meter 22 is brought into close contact with the rubber pad 99 attached to the fixing tank 93.

Thereafter, when the stop knob 98 is rotated clockwise, the movable jaw 95 moves forward toward the right side of the laser distance meter 22 by the transfer screw 97, and the ablation spring 96 is compressed.

At this time, when the rubber pad 99 attached to the movable jaw 95 is in close contact with the right side of the laser distance meter 22 and the stop knob 98 is strongly turned clockwise, the fixed jaw 93 and the movable jaw 95 A laser range finder 22 located in between is fixed under pressure.

Thereafter, the horizontal bar 60 and the extension bar 300 are placed on the upper surface 21 of the lower structure 20, and the step spacing member 100 installed on the left height control arm 40 and the right height control arm 50 When the front end of the long spacer 200 is brought into close contact with the end surface 23, the left height control arm 40 and the right height control arm 50 are installed on the chamfered edge 24 of the lower structure 20.

Then, when adjusting the height of the laser beam (B) output from the laser distance meter 22 to the bolt head of the anchor bolt 25, loosen the pressure adjusting nut 80 and remove the pressure adjusting nut 80 from the rear eye ring 51. When spaced apart, the front eye ring 41 and the ring spacer 70 maintain a stopped state by the pressure applied from the friction spring 82.

At this time, the friction force applied to the front eye ring 41 and the ring spacer 70 from the friction spring 82 is changed according to the distance between the rear eye ring 51 and the pressure adjusting nut 80 .

Then, as shown in FIG. 12, when the distance between the left height control arm 40 and the right height control arm 50 is widened, the height of the laser distance meter 22 is lower than before the change, and as shown in FIG. 11, the left When the distance between the height adjusting arm 40 and the right height adjusting arm 50 is narrowed, the height of the laser distance meter 22 becomes higher than before the change.

At this time, the plunger bolt 74 installed in the ring spacer 70 is rotated together with the ring spacer 70, and the steel ball 73 provided in the plunger bolt 74 is in the stop groove 41g formed in the front eye ring 41. The process of getting out or protruding into the stop groove 41g is repeated.

In this way, when the steel ball 73 provided in the plunger bolt 74 and the stop groove 41g formed in the front eye ring 41 are caught, the left height control arm 40 and the right height control arm 50 intermittently Since it is stopped, it is possible to conveniently position the left height control arm 40 and the right height control arm 50, and prevent the left height control arm 40 and the right height control arm 50 from being spread by their own weight. It can be prevented.

On the other hand, the holder fixing plate 30 and the front eye ring 41 are maintained in a stopped state by the frictional force caused by the pressure applied from the friction spring 82. At this time, when the laser distance meter 22 is rotated, the laser distance meter 22 ) can finely adjust the height of the laser beam (B) output from it.

At this time, if you hold the laser distance meter 22 with your hand and rotate it clockwise or counterclockwise while holding the left height adjustment arm 40 and the right height adjustment arm 50 with your hand to prevent them from rotating, the laser distance meter ( 22), the laser holder 90, the holder fixing plate 30, the shaft 31, the male screw part 32, and the pressure adjusting nut 80 are rotated.

In this process, as shown in FIG. 13, since the laser beam B output from the laser distance meter 22 has an eccentric rotation radius E that is separated from the rotation center of the shaft 31 by a certain distance, the laser beam B ) can be finely changed.

In this way, in a state in which the laser beam (B) is matched to the bolt head of the anchor bolt (25), by turning the loosened pressure adjusting nut (80) and bringing it into close contact with the rear eye ring (51), the holder fixing plate (30) and the pressure adjusting nut (80) ) The front eye ring 41, the ring spacer 70, and the rear eye ring 51 located between the are strongly pressed and cannot rotate. At this time, the edge distance may be measured using a laser distance meter 22.

As shown in FIG. 18, since the laser beam B output from the laser distance meter 22 is reflected from the side of the bolt head of the anchor bolt 25, the value measured from the laser distance meter 22 corresponds to the anchor bolt 25 ) to get the edge distance.

20: substructure 21: upper surface
22: laser distance meter 22e: end
23: edge surface 30: holder fixing plate
31: shaft 32: male thread
40: left height control arm 40h, 50h: fastening hole
41: front eye ring 41g: stop groove
50: right height adjustment arm 51: rear eye ring
60: horizontal bar 70: ring spacer
71: plunger screw hole 72: spring
73: steel ball 74: plunger bolt
80: pressure adjusting nut 81: spring storage chamber
82: friction spring 90: laser holder
91: reference block 91a: distance measurement reference surface
92: support plate 92h: guide hole
92s: screw hole 93: fixed tank
94: slide shaft 95: movable tank
95h: idle hole 96: spread spring
97: transfer screw 98: stop knob
100: short spacing material 200: long spacing material
100t,200t: tapped hole 102,202: fixing screw
T1,T2,T3,T4: thickness L1,L2: length
300: extension bar 301: annular protrusion
302: stud bolt 61,303: center hole
62,304: female screw hole

Claims (4)

Holder fixing plate 30 having a constant thickness;
A shaft 31 formed at the front center of the holder fixing plate 30;
a male screw portion 32 formed at the center of an end of the shaft 31;
a left height control arm 40 and a right height control arm 50 that are spaced apart from each other in the front and rear directions and meet in an inverted V shape;
Horizontal bars 60 supported on the upper surface 21 of the bridge substructure 20 and installed on the left height control arm 40 and the right height control arm 50, respectively;
a flat donut-shaped front eye ring 41 formed at an upper end of the left height adjusting arm 40 so as to be supported on an outer circumferential surface of the shaft 31 and closely adhered to the front surface of the holder fixing plate 30;
a flat donut-shaped rear eye-ring 51 formed at an upper end of the right height-adjusting arm 50 and spaced apart at regular intervals concentrically with the front eye-ring 41;
a ring spacer 70 supported on an outer circumferential surface of the shaft 31 between the front eye-ring 41 and the rear eye-ring 51 and rotated together with the rear eye-ring 51;
a plunger screw hole 71 formed eccentrically from the center of the ring spacer 70;
a plunger bolt 74 installed in the plunger screw hole 71;
a steel ball 73 receiving an elastic force in a protruding direction toward the front eye ring 41 by a spring 72 embedded in the plunger bolt 74;
stop grooves (41g) arranged in a circular shape on one side of the front eye ring (41) and determining the position of the steel ball (73);
a pressure adjusting nut 80 coupled to the male screw portion 32;
a spring storage chamber 81 formed at a constant depth at the center of one side end of the pressure adjusting nut 80;
a friction spring 82 positioned in the spring storage chamber 81 so that the male screw portion 32 passes through the center and repelled between the rear eye ring 51 and the pressure adjusting nut 80;
A laser holder 90 installed on the holder fixing plate 30 and holding or releasing the biting of the laser distance meter 22;
Edge distance measuring device for bridge safety diagnosis, characterized in that it comprises a. According to claim 1,
The laser holder 90,
A reference block 91 having a distance measurement reference surface 91a in close contact with the end 22e of the laser distance meter 22 and installed on the rear surface of the holder fixing plate 30;
a support plate 92 formed horizontally on the reference block 91 and supporting a lower surface of the laser distance meter 22;
a fixed jaw 93 vertically installed on the left side of the support plate 92 and in close contact with the left side of the laser distance meter 22;
a pair of guide holes 92h penetrating the left and right side surfaces of the supporting plate 92 in a horizontal direction;
a pair of slide shafts 94 inserted into the guide holes 92h and moving in left and right directions;
A movable jaw 95 coupled to the right end of the slide shaft 94 and pressing the right side of the laser distance meter 22;
The slide shaft 94 is passed through the center, and the spread spring 96 repelled between the support plate 92 and the movable jaw 95;
Screw holes 92s penetrating the support plate 92 from side to side;
an idle hole 95h formed in the movable tank 95 so as to be centered with the screw hole 92s;
a feed screw 97 coupled to the screw hole 92s through the idle hole 95h;
a stop knob 98 installed at the right end of the transfer screw 97 and stopping the movable jaw 95 by resisting the extension of the ablation spring 96;
Edge distance measuring device for bridge safety diagnosis, characterized in that it comprises a. According to claim 2,
fastening holes 40h and 50h formed in series at regular intervals along the longitudinal direction of the left height-adjusting arm 40 and the right height-adjusting arm 50;
a step spacer 100 positioned between the end surface 23 of the lower structure 20 and the left height adjusting arm 40;
a long spacer 200 positioned between the end surface 23 of the lower structure 20 and the right height adjusting arm 50;
tap holes 100t and 200t respectively formed at the centers of the short spacer 100 and the long spacer 200;
Including, fixing screws 102 and 202 coupled to the tapped holes 100t and 200t through the fastening holes 40h and 50h,
The length L1 of the step spacer 100 is formed to the same length as the sum of the thickness T2 of the holder fixing plate 30 and the thickness T1 of the reference block 91,
The length L2 of the long spacer 200 is the length of the short spacer 100 (the sum of the thickness T3 of the front eye ring 41 and the thickness T4 of the ring spacer 70). Edge distance measuring device for bridge safety diagnosis, characterized in that it is formed by forming the same length as the value added to L1). According to claim 1,
An extension bar 300 connected to the front end of the horizontal bar 60 in the longitudinal direction;
circular center holes 61 and 303 respectively formed at a predetermined depth at the center of the front end of the horizontal bar 60 and the extension bar 300;
a female screw hole (62) (304) formed at the inner center of the center hole (61) (303) and having an inner diameter smaller than that of the center hole (61) (303);
an annular protrusion 301 formed at the rear end of the extension bar 300 and inserted into the center hole 61 (303);
a stud bolt 302 formed at the center of an end of the annular protrusion 301 and coupled to the female screw holes 62 and 304;
Edge distance measuring device for bridge safety diagnosis, characterized in that it comprises a.

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