JP7229791B2 - Jig - Google Patents

Description

TECHNICAL FIELD The present invention relates to a technique of a jig for supporting a measuring unit having a laser rangefinder.

Conventionally, techniques for pressing concrete into steel pipes for CFT structures are publicly known. For example, it is as described in Patent Document 1.

In Patent Document 1, concrete is injected by a pump truck from the injection port at the bottom of the steel pipe column, and the pressure of the pump truck pushes the concrete up to the upper end of the steel pipe column, thereby filling the internal space of the steel pipe column with concrete. method is described.

In the method described in Patent Document 1, a level measuring instrument for measuring the height of concrete in the internal space of the steel pipe column is provided at the top end of the steel pipe column. The level measuring instrument is configured to measure the distance from the top of the steel pipe column to the top surface of the concrete being filled using visible light (laser).

It is difficult for the above-described level measuring instrument to accurately measure the height of the concrete if the pointing direction with respect to the upper surface of the concrete is deviated. Therefore, there is a demand for a jig that supports the level measuring instrument in such a manner as to prevent the pointing direction from deviating.

JP-A-11-131807

The present invention has been made in view of the above circumstances, and the problem to be solved is to support a measurement unit directed to the top of concrete in such a manner as to prevent deviation of the pointing direction. It is intended to provide a jig that can be used.

The problems to be solved by the present invention are as described above, and the means for solving the problems will now be described.

That is, in claim 1, a jig for supporting a measuring unit having a laser rangefinder for measuring the distance from the upper side of a steel pipe for CFT structure to the top of concrete pressed into the steel pipe, a support portion installed on the steel pipe; a unit holding portion that is supported by the support portion above the steel pipe and holds the measurement unit so that the measurement unit faces downward; movement suppressing means for suppressing movement of the support section with respect to a surface, the support section having a mounting surface on which the unit holding section is mounted, and the unit holding section having the mounting surface and an angle adjustment capable of adjusting the angle of the unit holding portion with respect to the support portion by adjusting the distance between the mounting surface and the facing surface at at least three points. means .
Further, in claim 2, a jig for supporting a measuring unit having a laser rangefinder for measuring the distance from the upper side of a steel pipe for CFT structure to the top of concrete pressed into the steel pipe, a support portion installed on the steel pipe; a unit holding portion that is supported by the support portion above the steel pipe and holds the measurement unit so that the measurement unit faces downward; movement suppressing means for suppressing movement of the support portion with respect to the surface, wherein the unit holding portion includes a cylindrical housing portion in which the measurement unit is housed, and at least three points inside the housing portion. and internal position adjusting means capable of adjusting the position of the measuring unit with respect to the accommodating portion by adjusting the distance between the side surface and the outer side surface of the measuring unit.

In claim 3 , the support part comprises at least three legs that are vertically extendable.

In claim 4 , the movement suppressing means has a magnet portion capable of switching between generation and non-generation of magnetic force.

In claim 5 , the mounting surface further comprises a positioning portion that is provided on the installation surface and enables positioning of the support portion with respect to the steel pipe.

In claim 6, the unit holding portion adjusts the distance between the inner surface of the accommodating portion and the outer surface of the measuring unit at least three points with respect to a tubular accommodating portion in which the measuring unit is accommodated. and an internal position adjusting means capable of adjusting the position of the measuring unit with respect to the accommodating portion.

As effects of the present invention, the following effects are obtained.

In claim 1, the measurement unit directed to the top of the concrete can be supported so as to be able to suppress deviation of the pointing direction.
In claim 2, the measuring unit oriented to the top of the concrete can be supported so as to be able to suppress deviation of the oriented direction.

In claim 3 , the measurement unit can be supported more favorably.

In claim 4 , the support part can be detachably fixed by using the iron plate laid on the installation floor.

In claim 5 , the measuring unit can be easily arranged so as to be oriented toward the top of the concrete inside the steel pipe.

In claim 6, the measurement unit can be supported more favorably.

Sectional drawing which showed the jig for top floors. The perspective view which showed the jig for top floors. The enlarged perspective view which showed the state which decomposed|disassembled the jig for top floors. The enlarged perspective view which showed the state which assembled|attached the jig for top floors. The top view which showed the unit holding|maintenance part of the state which accommodated the measurement unit. FIG. 4 is a plan view showing the unit holding portion in a state where the measurement unit is not accommodated; Sectional drawing which showed the jig for intermediate floors. The perspective view which showed the jig for intermediate floors. The enlarged perspective view which showed the jig for intermediate floors.

Hereinafter, the front-rear direction, the left-right direction, and the up-down direction will be defined and explained based on the arrows in the drawings.

A jig 10 according to one embodiment of the present invention supports the measuring unit 1 . The measuring unit 1 measures the press-in speed of concrete 8 press-fitted into steel pipes 7 constituting columns of a building having a CFT structure (concrete-filled steel pipe structure).

1 and 2, the configuration of a column of a CFT structure building (hereinafter referred to as a "filled steel pipe concrete column 6") will be described.

The filled steel pipe concrete column 6 is formed by filling the internal space of the steel pipe 7 with concrete 8, as shown in FIG. The steel pipe 7 is a rectangular tubular member made of steel (iron). The steel pipe 7 is formed over each floor of the building. The steel pipe 7 has an insertion hole 7a and a diaphragm 7b.

The insertion hole 7a is a hole formed so as to pass through the side surface of the steel pipe 7 in the front-rear direction. Concrete 8 is press-fitted into the internal space of the steel pipe 7 via the insertion hole 7a. The insertion hole 7a is provided at a position corresponding to at least the ground floor Fa of the building. Also, the insertion hole 7a is provided at a position corresponding to a predetermined intermediate floor Fn as required (see FIG. 7).

Further, the side surface of the steel pipe 7 is provided with a predetermined steam release hole (not shown) for releasing steam from the internal space of the steel pipe 7 . A plurality of steam vent holes (for example, each floor) are provided at predetermined intervals along the vertical direction.

The diaphragm 7b is a horizontal stiffener that transfers the stress of the beam (not shown) to the filled steel pipe concrete column 6. A diaphragm 7 b is provided in the internal space of the steel pipe 7 . A plurality of diaphragms 7b are provided at predetermined intervals along the vertical direction of the steel pipe 7 so as to correspond to the positions where the beams of each floor of the building are provided. The diaphragm 7b has a plate shape arranged with its thickness direction directed vertically. The diaphragm 7b has a rectangular shape in plan view. The diaphragm 7b has a placement hole 7c and an air hole 7d.

The placement hole 7 c shown in FIG. 2 is a hole provided so that the concrete 8 can pass through the internal space of the steel pipe 7 . The driving hole 7c is provided so as to penetrate the diaphragm 7b in the thickness direction. The driving hole 7c is provided in the central portion of the diaphragm 7b in plan view. The inner diameter of the placement hole 7c is appropriately set from the viewpoint of strength and suitable filling of the concrete 8 .

7 d of air holes are holes for extracting air from the internal space of the steel pipe 7 . 7 d of air holes are provided so that the thickness direction of the diaphragm 7b may be penetrated. 7 d of air holes are provided in the four corners in planar view of the diaphragm 7b. The inner diameter of the air hole 7d is formed to be smaller than the inner diameter of the driving hole 7c.

Next, a method for constructing the filled steel pipe concrete column 6 will be described with reference to FIG.

First, the concrete 8 from the pump truck brought to the ground floor Fa of the building is press-fitted into the internal space of the steel pipe 7 through the insertion hole 7a provided on the ground floor Fa of the steel pipe 7 . As a result, the internal space of the steel pipe 7 is filled with the concrete 8 so as to push up the top end 8a of the concrete 8 from below.

The concrete 8 press-fitted into the internal space of the steel pipe 7 is press-fitted to the upper story side through the placement hole 7c of the diaphragm 7b. When the concrete 8 is filled up to the upper end of the steel pipe 7, the press-fitting of the concrete 8 is stopped. By solidifying the concrete 8 filled in this manner, the filled steel pipe concrete column 6 is formed. In the above example, the concrete 8 is press-fitted on the ground floor Fa. is also possible.

Next, the measurement unit 1 will be described with reference to FIGS. 1 to 5. FIG.

The measurement unit 1 is capable of acquiring information on the concrete 8 pressed into the internal space of the steel pipe 7 . The measurement unit 1 includes an illumination section 2, a camera section 3, a laser rangefinder 4, and a case section 5.

The illumination unit 2 shown in FIG. 5 illuminates the internal space of the steel pipe 7 . The lighting section 2 has a predetermined light emitting section such as a light emitting diode.

The camera section 3 images the internal space of the steel pipe 7 . The camera section 3 has a predetermined lens section (not shown).

The laser range finder 4 can measure the distance from above the concrete 8 press-fitted into the internal space of the steel pipe 7 to the top end 8 a of the concrete 8 . The laser rangefinder 4 has a predetermined laser beam irradiation section (not shown). As shown in FIG. 1, the laser range finder 4 is directed to the top edge 8a of the concrete 8 located below and irradiates a laser beam. By measuring the time, the distance to the top 8a of the concrete 8 is measured.

The case portion 5 accommodates the illumination portion 2, the camera portion 3, and the laser rangefinder 4. As shown in FIG. The case portion 5 has a substantially cylindrical shape with both ends closed. The case portion 5 is formed so that the light emitting portion of the illumination portion 2, the lens portion of the camera portion 3, and the laser beam irradiation portion of the laser rangefinder 4 are exposed on the bottom surface. In the present embodiment, the laser beam irradiation section is positioned at the center of the lower surface of the case section 5 as viewed from the bottom.

A cable 5a used for power supply and information output is connected to the illumination unit 2, the camera unit 3, and the laser rangefinder 4 described above. The cable 5a is wired from the upper surface of the case portion 5 to the outside. Image information captured by the camera section 3 and measurement results obtained by the laser rangefinder 4 are output via the cable 5a.

Image information from the camera unit 3 and measurement results from the laser rangefinder 4 are output to the control unit 290 shown in FIG. The control unit 290 includes an arithmetic device such as a CPU (Central Processing Unit), a storage device such as a ROM (Read Only Memory) and a RAM (Random Access Memory), and the like. The control unit 290 can calculate the press-in speed of the concrete 8 in the internal space of the steel pipe 7 using the measurement results obtained by the laser rangefinder 4 .

The pressing speed of the concrete 8 and the image information of the camera unit 3 are displayed via a predetermined monitor. As a result, the worker who presses the concrete 8 can control the pressing of the concrete 8 while checking the speed of the concrete 8 and the state of the internal space of the steel pipe 7 .

Next, a jig 10 according to one embodiment of the present invention will be described.

The jig 10 supports the measuring unit 1 above the top end 8 a of the concrete 8 press-fitted into the internal space of the steel pipe 7 . The jig 10 includes a top floor jig 100 and an intermediate floor jig 200 .

First, the top floor jig 100 will be described below with reference to FIGS. 1 to 5 .

The top floor jig 100 supports the measurement unit 1 above the upper end of the steel pipe 7 . As shown in FIGS. 1 and 2, the top floor jig 100 is installed on the top floor Fr (rooftop floor) of the building where the upper ends of the steel pipes 7 are located. Specifically, the top floor jig 100 is placed on the upper surface 9a of the iron plate 9 laid on the floor surface of the top floor Fr before the concrete 8 of the roof slab is cast. The top floor jig 100 includes a support portion 110 , a unit holding portion 140 and a positioning portion 180 .

The support part 110 is installed with respect to the iron plate 9 . The support portion 110 includes a leg portion 120 and a mounting portion 130 .

The leg portion 120 is grounded on the upper surface 9 a of the iron plate 9 . In this embodiment, three legs 120 are provided. That is, in the present embodiment, the support portion 110 constitutes a tripod grounded on the upper surface 9a of the iron plate 9 at three points by the three legs 120. As shown in FIG. The leg portion 120 has an elongated shape and is arranged with its longitudinal direction directed obliquely upward. The leg portion 120 is extendable along the longitudinal direction. Leg 120 comprises outer leg 121 and inner leg 122 .

The outer leg portion 121 has an elongated shape. The outer leg portion 121 has an internal space capable of accommodating an elongated member (an inner leg portion 122 to be described later).

The inner leg portion 122 has an elongated shape corresponding to the internal space of the outer leg portion 121 . The inner leg portion 122 is accommodated in the inner space of the outer leg portion 121 so as to be movable in the longitudinal direction. Movement of the inner leg 122 relative to the outer leg 121 causes the leg 120 to expand and contract. By extending and contracting as described above, the leg portion 120 can be adjusted to an arbitrary length. Further, the leg portion 120 can be held at an arbitrary length by the expansion and contraction. The inner leg 122 is provided with movement restraint means 123 .

The movement suppressing means 123 suppresses the movement of the support portion 110 with respect to the iron plate 9 . The movement suppressing means 123 is provided at the lower end portion (oblique lower end portion) of the inner leg portion 122 . The movement suppressing means 123 is provided such that its lower surface is in contact with the upper surface 9 a of the iron plate 9 . The movement suppressing means 123 includes a case portion 124 , a magnet portion 125 and a switching portion 126 .

The case portion 124 constitutes an outer shell of the movement suppressing means 123 . The illustrated example shows an example in which the case portion 124 has a substantially rectangular parallelepiped shape.

The magnet part 125 is capable of generating magnetic force. The magnet portion 125 is housed in the internal space of the case portion 124 . The magnet portion 125 can generate magnetic force on the lower surface of the case portion 124 . The magnet part 125 can switch between generation and non-generation of magnetic force in the magnet part 125 .

The switching unit 126 switches between generation and non-generation of magnetic force in the magnet unit 125 . The switching portion 126 protrudes from the side surface of the case portion 124 and can be rotated. The switching portion 126 switches between a state in which the magnetic force is generated by the magnet portion 125 (magnetic force generation state) and a state in which the magnetic force is not generated (non-generation state).

The mounting portion 130 is connected to the upper end portion (oblique upper end portion) of the outer leg portion 121 . The mounting portion 130 has a plate shape arranged with the thickness direction generally directed in the vertical direction. A unit holding portion 140 to be described later is placed on the upper surface 131 of the placing portion 130 .

The mounting portion 130 has a substantially equilateral triangular shape in plan view. The mounting portion 130 has three legs 120 (outer legs 121) connected to its three sides in plan view. Specifically, the mounting portion 130 has three rotation shafts whose axial directions are oriented in the directions in which the three sides extend, and the leg portions 120 are rotatably connected to the rotation shafts. be. Further, the mounting portion 130 has an opening portion 132 .

The opening 132 is a hole penetrating through the mounting portion 130 in the thickness direction. The opening 132 is provided in the central portion of the mounting portion 130 in plan view. The opening 132 has a circular shape in plan view.

The support part 110 described above can adjust the angle of the mounting part 130 with respect to the upper surface of the iron plate 9 by appropriately extending and contracting the three leg parts 120 while being installed on the iron plate 9 .

With the support portion 110 installed on the iron plate 9 , the movement suppressing means 123 is fixed to the iron plate 9 by operating the switching portion 126 to bring the movement suppressing means 123 into a magnetic force generating state. Thereby, the movement of the support portion 110 with respect to the iron plate 9 is suppressed. In addition, the support portion 110 can release the fixation of the movement suppressing means 123 to the iron plate 9 by setting the movement suppressing means 123 to the non-generated state by operating the switching portion 126 . This allows the support portion 110 to move relative to the iron plate 9 .

The unit holding section 140 holds the measurement unit 1 . The unit holding portion 140 is supported by the support portion 110 above the steel pipe 7 . The unit holding section 140 includes a housing section 150 , angle adjustment means 160 and internal position adjustment means 170 .

The accommodation section 150 accommodates the measurement unit 1 . The housing portion 150 has a bottomed cylindrical shape with an open top. The housing portion 150 includes a bottom portion 151 , side portions 154 and flange portions 156 .

A bottom portion 151 shown in FIGS. 3, 5 and 6 constitutes the bottom surface of the housing portion 150 . As shown in FIG. 5 , when the measurement unit 1 is housed in the housing portion 150 , the bottom surface of the measurement unit 1 contacts the top surface (bottom surface) of the bottom portion 151 . The bottom 151 has a protrusion 152 and an opening 153 .

The protrusion 152 protrudes downward. The projecting portion 152 has a shape whose diameter is smaller than that of a side portion 154, which will be described later. The protrusion 152 has a cylindrical shape. The projecting portion 152 is provided at the central portion of the bottom portion 151 in bottom view. The protrusion 152 is inserted through the opening 132 of the mounting portion 130 . The outer diameter dimension of the protruding portion 152 is a dimension that roughly corresponds to the inner diameter dimension of the opening portion 132 of the mounting portion 130 .

The opening 153 is a hole that vertically opens the bottom 151 . The opening 153 is provided in the central portion of the bottom 151 so as to overlap with the opening 132 of the mounting portion 130 in plan view. As shown in FIG. 5, the opening 153 overlaps the illumination section 2, the camera section 3, and the laser rangefinder 4 of the measurement unit 1 in plan view when the measurement unit 1 is accommodated in the accommodation section 150. be provided. In addition, the opening 153 overlaps with the light emitting portion of the illumination portion 2, the lens portion of the camera portion 3, and the laser beam irradiation portion of the laser rangefinder 4 in plan view (bottom view). As a result, with the measurement unit 1 housed in the housing section 150, the light emitting section of the illumination section 2, the lens section of the camera section 3, and the laser beam irradiation section of the laser rangefinder 4 are downwardly positioned via the opening 153. can be exposed.

The side portion 154 constitutes the outer side surface and the inner side surface of the housing portion 150 . The inner diameter dimension of the side portion 154 is formed larger than the outer diameter dimension of the measurement unit 1 (case portion 5). Thereby, a gap is formed between the inner surface of the side portion 154 and the outer surface of the measuring unit 1 when the measuring unit 1 is accommodated in the accommodating portion 150 . Side 154 includes a threaded hole 155 .

The screw hole 155 is a hole penetrating through the side portion 154 in the thickness direction (inward and outward directions). Threaded hole 155 constitutes an internal thread. A threaded hole 155 is formed in the upper portion of the side portion 154 . Three screw holes 155 are formed in the side portion 154 . The three screw holes 155 are arranged at equal intervals in the circumferential direction on the side portion 154 .

The flange portion 156 is a portion formed at the lower end portion of the side portion 154 so as to expand radially outward. The flange portion 156 has a plate shape that is annular in plan view. A lower surface 157 of the flange portion 156 faces the upper surface 131 of the mounting portion 130 . The flange portion 156 has a threaded hole 158 and a spirit level 159 .

The threaded hole 158 is a hole penetrating through the flange portion 156 in the vertical direction. Threaded hole 158 constitutes an internal thread. Threaded holes 158 are formed at three locations in the flange portion 156 . The three screw holes 158 are arranged at equal intervals in the circumferential direction in the flange portion 156 .

The spirit level 159 is for checking the inclination (horizontal state) of the flange portion 156 . A spirit level 159 is provided on the upper surface of the flange portion 156 . The spirit level 159 has a circular shape in plan view. This embodiment shows an example in which the level 159 is a bubble tube level in which liquid and air bubbles are sealed inside a container. The spirit level 159 is not limited to such a mode, and various types such as a digital type and a laser type can be adopted.

The angle adjustment means 160 shown in FIGS. 3 to 5 is capable of adjusting the angle of the accommodation portion 150 (unit holding portion 140) with respect to the support portion 110. FIG. The angle adjustment means 160 are provided at positions corresponding to the screw holes 158 of the flange portion 156 . The angle adjusting means 160 has a threaded portion 161 and an operating portion 162 .

The threaded portion 161 is inserted through the threaded hole 158 of the flange portion 156 . The threaded portion 161 constitutes a male thread that is screwed into the threaded hole 158 . The threaded portion 161 is elongated in the vertical direction. A lower end portion of the threaded portion 161 can contact the upper surface 131 of the mounting portion 130 .

The operation part 162 enables the operation of the screw part 161 . The operating portion 162 is provided at the upper end portion of the threaded portion 161 . The operating portion 162 has a shape with a larger diameter than the threaded portion 161 . The operating portion 162 is positioned above the upper surface of the flange portion 156 . By rotating the operating portion 162 about the axial direction of the threaded portion 161 , the lower end portion of the threaded portion 161 can be moved back and forth with respect to the lower surface 157 of the flange portion 156 .

By appropriately operating the three angle adjusting means 160 as described above, the distance between the upper surface 131 of the mounting portion 130 and the lower surface 157 of the flange portion 156 can be adjusted at three points. Accordingly, by adjusting the angle of the housing portion 150 with respect to the support portion 110 , the measurement unit 1 can be preferably directed toward the top end 8 a of the concrete 8 in the internal space of the steel pipe 7 .

The internal position adjusting means 170 can adjust the position of the measurement unit 1 with respect to the housing portion 150 . The internal position adjusting means 170 are provided at positions corresponding to the screw holes 155 of the side portion 154 . The internal position adjusting means 170 comprises a threaded portion 171 and an operating portion 172 .

The threaded portion 171 is inserted through the threaded hole 155 of the side portion 154 . The threaded portion 171 constitutes a male thread that is screwed into the threaded hole 155 . The threaded portion 171 is elongated in the radial direction (inward-outward direction) of the side portion 154 . The inner end of the threaded portion 171 can abut against the outer surface of the measurement unit 1 (case portion 5).

The operating portion 172 enables the screw portion 171 to be operated. The operating portion 172 is provided at the upper end portion of the threaded portion 171 . The operating portion 172 has a shape with a larger diameter than the threaded portion 171 . The operating portion 172 is located outside the outer surface of the side portion 154 . By rotating the operating portion 172 about the axial direction of the threaded portion 171 , the inner end portion of the threaded portion 171 can be advanced or retracted with respect to the inner surface of the side portion 154 .

By appropriately operating the three internal position adjusting means 170 as described above, the distance between the inner surface of the housing portion 150 and the outer surface of the measurement unit 1 can be adjusted at three points. Accordingly, by adjusting the position of the measurement unit 1 with respect to the housing portion 150 , the measurement unit 1 can be preferably oriented toward the top end 8 a of the concrete 8 in the internal space of the steel pipe 7 .

The positioning portion 180 shown in FIG. 2 can position the support portion 110 with respect to the steel pipe 7 . The positioning portion 180 is provided on the upper surface 9 a of the iron plate 9 . A positioning portion 180 indicates a position where the movement suppressing means 123 is grounded. The positioning portion 180 is positioned such that the mounting portion 130 of the support portion 110 is positioned approximately in the central portion of the internal space of the steel pipe 7 in plan view with the movement suppressing means 123 grounded at the position indicated by the positioning portion 180 . provided in The positioning part 180 may constitute a marking provided directly on the iron plate 9 or may be a plate-like (mat-like) member laid on the iron plate 9 .

The top floor jig 100 formed as described above is installed, for example, on the top floor Fr as follows.

First, the movement suppressing means 123 (case portion 124 ) of the support portion 110 is grounded at the position indicated by the positioning portion 180 on the upper surface 9 a of the iron plate 9 . This enables positioning of the support portion 110 with respect to the steel pipe 7 .

Next, the movement suppressing means 123 is fixed to the iron plate 9 by operating the switching portion 126 to bring the movement suppressing means 123 into the magnetic force generating state. Next, by appropriately extending and contracting the three legs 120 of the supporting portion 110, the angle of the mounting portion 130 with respect to the upper surface of the iron plate 9 is adjusted so as to approach a horizontal state.

Next, the unit holding portion 140 is placed on the placing portion 130 of the support portion 110 . In this state, the projecting portion 152 of the unit holding portion 140 is inserted through the opening portion 132 of the mounting portion 130 . Next, by appropriately operating the three angle adjustment means 160 provided on the flange portion 156 of the unit holding portion 140, the angle of the housing portion 150 with respect to the support portion 110 is adjusted so that the unit holding portion 140 is in a horizontal state. adjust.

Next, the measurement unit 1 is accommodated in the accommodation portion 150 of the unit holding portion 140 . In this state, the measurement unit 1 is held by the unit holding section 140 so as to be in a horizontal state. Next, the three internal position adjusting means 170 provided on the side portion 154 of the unit holding portion 140 are appropriately operated. As a result, it is possible to finely adjust the position of the measurement unit 1 so that it can be appropriately oriented with respect to the top end 8 a of the concrete 8 in the internal space of the steel pipe 7 . The installation procedure described above is an example, and the installation procedure of the top floor jig 100 is not limited to the above example.

The intermediate floor jig 200 will be described below with reference to FIGS. 7 to 9 .

The intermediate floor jig 200 supports the measuring unit 1 on the intermediate floor Fn of the building. As shown in FIGS. 7 and 8 , the intermediate floor jig 200 is installed in the middle of the steel pipe 7 in the vertical direction. The intermediate floor jig 200 includes a support portion 210 , an arm portion 240 , a fixing means 250 and a bracket 280 .

The support portion 210 is inserted through the insertion hole 7a of the steel pipe 7 on the middle floor Fn of the building. The support portion 210 supports the measurement unit 1 so that the measurement unit 1 faces downward inside the steel pipe 7 . The support portion 210 is elongated in the front-rear direction. The support portion 210 includes an outer rail portion 220 and an inner rail portion 230 .

The outer rail portion 220 constitutes the outer portion of the support portion 210 . The outer rail portion 220 is elongated in the front-rear direction. The outer rail portion 220 has a substantially rectangular outer shape in a cross-sectional view. Further, the outer rail portion 220 has a substantially rectangular shape in a cross-sectional view, and has an internal space capable of accommodating an inner rail portion 230, which will be described later.

The inner rail portion 230 constitutes the inner portion of the support portion 210 . The inner rail portion 230 is elongated in the front-rear direction. The inner rail portion 230 has a substantially rectangular outer shape in a cross-sectional view. The inner rail portion 230 is accommodated in the inner space of the outer rail portion 220 so as to be movable in the longitudinal direction. That is, the inner rail portion 230 and the outer rail portion 220 are movable relative to each other. The inner rail portion 230 has a wiring space 231 .

The wiring space 231 is a space formed inside the inner rail portion 230 to allow wiring. The wiring space 231 is formed to penetrate the inner rail portion 230 in the longitudinal direction. In this embodiment, a plurality of wiring spaces 231 are formed at predetermined positions of the inner rail portion 230 .

The arm portion 240 is provided so as to extend in the left-right direction with respect to the outer rail portion 220 . Arm portion 240 is provided at the rear end portion of outer rail portion 220 . The arm portion 240 is provided so that both side portions in the left-right direction are positioned on both sides in the left-right direction of the insertion hole 7a. The arm portion 240 comprises a first piece portion 241 and a second piece portion 242 .

The first piece 241 has a plate shape with the thickness direction directed vertically. The upper surface of the first piece portion 241 is fixed to the lower surface of the rear end portion of the outer rail portion 220 . Holes 241a are formed vertically through both sides of the first piece 241 in the left-right direction.

The second piece portion 242 has a plate shape with the thickness direction oriented in the front-rear direction. The second piece 242 is provided to extend downward from the front end of the first piece 241 . That is, the arm portion 240 is substantially L-shaped in a cross-sectional view.

The fixing means 250 detachably fixes the front side and the rear side of the support portion 210 to the steel pipe 7 . Securing means 250 comprises front securing means 260 and rear securing means 270 .

The front-side fixing means 260 fixes the front-side portion of the outer rail portion 220 to the rearward inner surface (backward inner surface) of the steel pipe 7 . As shown in FIG. 8, the front-side fixing means 260 is fixed to a portion of the inner surface facing the rear of the steel pipe 7 that overlaps the insertion hole 7a in a front view. The front fixing means 260 is provided at the front end of the outer rail portion 220 . The front side fixing means 260 is provided so as to be rotatable with respect to the outer rail portion 220 about a rotation axis extending in the front-rear direction. The front fixing means 260 includes a case portion 261 , a magnet portion 262 and a switching portion 263 .

The case portion 261 constitutes the outer shell of the front fixing means 260 . The illustrated example shows an example in which the case portion 261 has a substantially rectangular parallelepiped shape.

The magnet part 262 is capable of generating magnetic force. The magnet portion 262 is housed in the internal space of the case portion 261 . The magnet portion 262 can generate a magnetic force on the front surface of the case portion 261 (the surface facing the inner surface facing the rear of the steel pipe 7). The magnet portion 262 can switch between generation and non-generation of magnetic force in the magnet portion 262 .

The switching section 263 switches between generation and non-generation of magnetic force in the magnet section 262 . The switching portion 263 protrudes from the rear surface of the case portion 261 and can be rotated. The switching portion 263 switches between a state in which magnetic force is generated by the magnet portion 262 (magnetic force generation state) and a state in which magnetic force is not generated (non-generation state) in accordance with the rotation operation.

The rear-side fixing means 270 fixes the rear-side portion of the outer rail portion 220 to the rear-facing outer surface of the steel pipe 7 (outer surface on the front side). The rear fixing means 270 are provided on both sides of the arm portion 240 in the left-right direction. The rear side fixing means 270 is fixed to the upper surface of the first piece portion 241 of the arm portion 240 . The rear fixing means 270 includes a case portion 271 , a magnet portion 272 , a switching portion 273 and a vertical position adjusting means 274 .

The case portion 271 constitutes the outer shell of the rear fixing means 270 . The illustrated example shows an example in which the case portion 271 has a substantially rectangular parallelepiped shape. A bottom hole portion 271a is formed through the bottom surface of the case portion 271 in the vertical direction. The lower surface hole portion 271a constitutes an internal thread.

The magnet part 272 is capable of generating magnetic force. The magnet portion 272 is housed in the internal space of the case portion 271 . The magnet portion 272 can generate a magnetic force on the front surface of the case portion 271 (the surface facing the rearward outer surface of the steel pipe 7). The magnet portion 272 can switch between generation and non-generation of magnetic force in the magnet portion 272 .

The switching section 273 switches between generation and non-generation of magnetic force in the magnet section 272 . The switching portion 273 protrudes from the rear surface of the case portion 271 and can be rotated. The switching portion 273 switches between a state in which a magnetic force is generated by the magnet portion 272 (magnetic force generation state) and a state in which the magnetic force is not generated (non-generation state) in accordance with the rotation operation.

The vertical position adjusting means 274 is capable of adjusting the vertical position of both lateral side portions of the arm portion 240 with respect to the fixed position of the case portion 271 with respect to the steel pipe 7 . The vertical position adjusting means 274 has a screw portion 275 and an operating portion 276 .

The screw portion 275 is inserted through the lower surface hole portion 271 a of the case portion 271 and the hole portion 241 a of the first piece portion 241 . The threaded portion 275 is elongated in the vertical direction. The threaded portion 275 is provided such that its upper end portion is located in the internal space of the case portion 271 . The threaded portion 275 is screwed into the hole portion 241 a of the case portion 271 . Further, the screw portion 275 is fixed to the first piece portion 241 so as to be rotatable about the axial direction and immovable in the axial direction while being inserted through the hole portion 241a of the first piece portion 241. be done. As a result, the case portion 271 (rear side fixing means 270 ) and the first piece portion 241 (arm portion 240 ) are fixed via the screw portion 275 .

The operating portion 276 enables the screw portion 275 to be operated. The operating portion 276 is provided at the lower end portion of the threaded portion 275 . The operating portion 276 has a shape with a larger diameter than the threaded portion 275 . The operating portion 276 is positioned below the lower surface of the first piece portion 241 .

By rotating the operation portion 276 about the axial direction of the threaded portion 275 , the case portion 271 screwed to the threaded portion 275 and the threaded portion 275 move along with the rotation of the threaded portion 275 . The distance between the rotatably fixed arm portion 240 and , can be adjusted. Thereby, the vertical position of the arm portion 240 with respect to the rear fixing means 270 can be adjusted.

The object to which the threaded portion 275 is screwed is not limited to the case portion 271, and various portions of the rear fixing means 270 can be employed. Further, the threaded portion 275 is not limited to being screwed to the rear side fixing means 270, and for example, the threaded portion 275 may be screwed to the first piece portion 241 (arm portion 240). . In this case, the screw portion 275 is fixed to the rear fixing means 270 so as to be rotatable and immovable in the axial direction.

The angles of the arm portion 240 and the support portion 210 can be adjusted by appropriately operating the two vertical position adjusting means 274 as described above. In addition, in the illustrated example, predetermined movement restricting portions 241b having elongated holes in the vertical direction are provided on both sides of the arm portion 240 in the left and right direction, and predetermined movement restricting portions 241b that are inserted into the elongated holes are provided on the side surfaces of the case portion 271. shows an example in which a protrusion 271b is provided. As a result, the vertical position of the case portion 271 can be adjusted within the range of the long hole.

The bracket 280 fixes the measurement unit 1 to the inner rail portion 230 . The bracket 280 has a substantially rectangular shape when viewed from the front. The bracket 280 has an upper piece portion 281 , a lower piece portion 282 and a side piece portion 283 .

The upper piece 281 has a plate shape with the thickness direction directed vertically. The lower surface of the upper piece portion 281 is fixed to the upper surface of the tip portion of the inner rail portion 230 via a predetermined stopper.

The lower piece portion 282 has a plate shape with the thickness direction directed vertically. The lower surface of the lower piece portion 282 is fixed to the upper surface of the measurement unit 1 (case portion 5) via a predetermined fastener.

The side piece portion 283 has a plate shape with the thickness direction oriented in the left-right direction. The side piece portion 283 connects the left and right ends of the upper piece portion 281 and the lower piece portion 282, respectively.

By fixing the measurement unit 1 to the inner rail portion 230 via the bracket 280 as described above, even if the stopper that fixes the upper piece portion 281 and the inner rail portion 230 comes off, the bracket Since the upper piece portion 281 of the measuring unit 280 is placed on the inner rail portion 230, it is possible to prevent the measurement unit 1 from falling.

Further, the measurement unit 1 fixed to the front end portion of the inner rail portion 230 as described above can be wired so that the cable 5 a is inserted through the wiring space 231 of the inner rail portion 230 .

The intermediate floor jig 200 formed as described above is installed, for example, on the intermediate floor Fn as follows.

First, on the intermediate floor Fn, the supporting portion 210 of the intermediate floor jig 200 is inserted through the insertion hole 7a of the steel pipe 7 while the measurement unit 1 is fixed. Here, the vertical dimension of the measurement unit 1 is larger than the inner diameter dimension of the insertion hole 7a. Therefore, when inserting the support portion 210 and the measurement unit 1 into the insertion hole 7a, the measurement unit 1 is appropriately inclined to the extent that it can be inserted into the insertion hole 7a.

Next, with the measuring unit 1 and the front part of the support part 210 positioned in the inner space of the steel pipe 7 , the intermediate floor jig 200 is moved forward, and the front fixing means 260 is moved to the inner surface of the steel pipe 7 facing the rear. , and the rear-side fixing means 270 is brought into contact with the outer surface of the steel pipe 7 facing the rear. At this time, the angles are appropriately adjusted so that the measurement unit 1 and the intermediate floor jig 200 are in a substantially horizontal state.

Next, by operating the switching portion 263 of the front side fixing means 260 and the switching portion 273 of the rear side fixing means 270, the front side fixing means 260 and the rear side fixing means 270 are brought into the state of generating magnetic force, whereby the intermediate floor jig is 200 is fixed to the steel pipe 7 at three points. In addition, when operating the switching portion 263 of the front-side fixing means 260, it is conceivable to use a predetermined jig elongated in the front-rear direction.

Next, by moving the inner rail portion 230 with respect to the outer rail portion 220, the longitudinal position of the measurement unit 1 is adjusted so that it is positioned at the central portion of the inner space of the steel pipe 7 in plan view. At this time, the amount of movement of the inner rail portion 230 relative to the outer rail portion 220 when the measurement unit 1 is positioned in the central portion of the internal space of the steel pipe 7 is indicated on either the outer rail portion 220 or the inner rail portion 230. It is also conceivable to provide a mark that serves as a guideline.

Next, the vertical position adjusting means 274 of the left and right rear side fixing means 270 are appropriately operated to adjust the angle of the measurement unit 1 about the rotation axis extending in the front-rear direction. As a result, it is possible to finely adjust the measurement unit 1 to be oriented at an angle that can be suitably oriented with respect to the top end 8a of the concrete 8 in the internal space of the steel pipe 7 . Note that the installation procedure described above is an example, and the installation procedure of the jig 200 for intermediate floors is not limited to the above-described example.

As described above, the top floor jig 100 (jig) according to one embodiment of the present invention is
A jig 100 for the top floor that supports a measurement unit 1 having a laser rangefinder 4 that measures the distance from the upper side of a steel pipe 7 for CFT structure to the top end 8a of concrete 8 pressed into the steel pipe 7,
a support portion 110 installed on the upper surface 9a (installation surface) of the iron plate 9;
a unit holding portion 140 that is supported by the support portion 110 above the steel pipe 7 and holds the measurement unit 1 so that the measurement unit 1 faces downward;
A movement suppressing means 123 that contacts the upper surface 9a of the iron plate 9 and suppresses movement of the support portion 110 with respect to the upper surface 9a;
is provided.

With such a configuration, the measuring unit 1 oriented toward the top end 8a of the concrete 8 can be supported so as to be restrained from being shifted in the oriented direction. That is, it is possible to hold the measurement unit 1 above the steel pipe 7 with the direction of orientation directed downward, and to support the measurement unit 1 so as to suppress its movement with respect to the upper surface 9 a of the iron plate 9 . As a result, the distance from the measurement unit 1 to the top end 8a of the concrete 8 can be accurately measured, and the pressing speed of the concrete 8 in the steel pipe 7 can be accurately measured using the distance.

Further, the support portion 110 is
It has at least three legs 120 that are vertically extendable.

With such a configuration, the measurement unit 1 can be supported more preferably. That is, by adjusting the angle of the unit holding part 140 with respect to the upper surface 9a of the iron plate 9 by expanding and contracting the leg part 120, the measuring unit 1 can be preferably oriented with respect to the top end 8a of the concrete 8 inside the steel pipe 7. can be done.

Further, the movement suppressing means 123 is
It has a magnet part 125 that can switch between generation and non-generation of magnetic force.

With such a configuration, the support section 110 can be detachably fixed using the iron plate 9 laid on the top floor Fr (installation floor).

In addition, the jig 100 for the top floor is
A positioning portion 180 is provided on the upper surface 9 a of the iron plate 9 and is capable of positioning the support portion 110 with respect to the steel pipe 7 .

With such a configuration, the measurement unit 1 can be easily arranged so as to be oriented toward the top end 8a of the concrete 8 inside the steel pipe 7 .

Further, the support portion 110 is
has an upper surface 131 (mounting surface) on which the unit holding portion 140 is mounted,
The unit holding portion 140 is
has a lower surface 157 (facing surface) facing the upper surface 131,
An angle adjustment means 160 is provided that can adjust the angle of the unit holding portion 140 with respect to the support portion 110 by adjusting the distance between the upper surface 131 and the lower surface 157 in at least three points. .

With such a configuration, the measurement unit 1 can be supported more preferably. That is, by adjusting the angle of the unit holding portion 140 with respect to the support portion 110 , the measurement unit 1 can be preferably directed toward the top end 8 a of the concrete 8 inside the steel pipe 7 .

Further, the unit holding portion 140 is
a cylindrical housing portion 150 in which the measuring unit 1 is housed;
Internal position adjustment means 170 capable of adjusting the position of the measuring unit 1 with respect to the accommodating portion 150 by adjusting the distance between the inner surface of the accommodating portion 150 and the outer surface of the measuring unit 1 in at least three points. and,
is provided.

With such a configuration, the measurement unit 1 can be supported more preferably. That is, by adjusting the position of the measurement unit 1 with respect to the housing portion 150 , the measurement unit 1 can be preferably directed toward the top end 8 a of the concrete 8 inside the steel pipe 7 .

In addition, the upper surface 131 according to this embodiment is an embodiment of the mounting surface according to the present invention.
Further, the lower surface 157 according to this embodiment is an embodiment of the facing surface according to the present invention.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above configuration, and various modifications are possible within the scope of the invention described in the claims.

For example, the uppermost floor jig 100 is not limited to the configuration of the embodiment described above. Specifically, the top floor jig 100 may be configured as follows.

In this embodiment, an example in which three leg portions 120 are provided in the support portion 110 is shown, but the present invention is not limited to such an aspect, and a configuration in which four or more leg portions 120 are provided may be employed.

Moreover, in the present embodiment, the movement suppressing means 123 includes the magnet portion 125, but the present invention is not limited to such an aspect. For example, the movement suppressing means 123 may include a member having a large coefficient of friction, such as rubber, to suppress the movement of the support portion 110 by friction.

Moreover, although the example which provided the movement suppression means 123 in the support part 110 was shown in this embodiment, it is not restricted to such an aspect. For example, a predetermined movement suppressing means 123 that suppresses the movement of the support portion 110 may be provided on the iron plate 9 side. Furthermore, a configuration in which the movement suppressing means 123 is not provided may be adopted.

Further, in this embodiment, an example in which the positioning portion 180 is provided is shown, but the present invention is not limited to such an aspect, and a configuration in which the positioning portion 180 is not provided may be employed.

In addition, in the present embodiment, the angle adjusting means 160 is configured to adjust the distance between the upper surface 131 of the mounting portion 130 and the lower surface 157 of the unit holding portion 140, but it is not limited to such an aspect. do not have. As the angle adjusting means 160, it is sufficient that the distance between the unit holding portion 140 and the supporting portion 110 can be adjusted at least three points in plan view.

Moreover, in the present embodiment, an example in which the angle adjustment means 160 is provided is shown, but the present invention is not limited to such an aspect, and a configuration in which the angle adjustment means 160 is not provided is also possible.

Further, in the present embodiment, the internal position adjusting means 170 is configured to adjust the distance between the inner surface of the housing portion 150 and the outer surface of the measurement unit 1, but the configuration is not limited to this. The internal position adjusting means 170 may be capable of adjusting the position of the measuring unit 1 with respect to the housing portion 150 at least three points.

Further, in the present embodiment, an example in which the internal position adjusting means 170 is provided has been shown, but the present invention is not limited to such an aspect, and a configuration in which the internal position adjusting means 170 is not provided may be employed.

Moreover, in the present embodiment, an example in which the jig 100 for the top floor is installed on the top floor Fr of the building is shown, but the configuration is not limited to this. That is, the top floor jig 100 is not limited to use on the top floor Fr, and can be installed on floors other than the top floor Fr (installation floor).

Further, the intermediate floor jig 200 is not limited to the configuration of the embodiment described above. Specifically, the intermediate floor jig 200 may be configured as follows.

In the present embodiment, the front side fixing means 260 and the rear side fixing means 270 are assumed to include the magnet portion 262 and the magnet portion 272, but are not limited to such an aspect. For example, the front side fixing means 260 and the rear side fixing means 270 may be fixed to the steel pipe 7 using predetermined suction cups. can be adopted.

Moreover, in the present embodiment, an example in which the arm portion 240 is provided so as to extend in the left-right direction has been shown, but the present invention is not limited to such an aspect. For example, the arm portion 240 may be provided so as to extend in a direction orthogonal to the longitudinal direction (front-rear direction) of the support portion 210 and in a direction other than the left-right direction.

Also, in the present embodiment, an example in which the cable 5a of the measurement unit 1 is wired in the wiring space 231 inside the inner rail portion 230 is shown, but the present invention is not limited to such an aspect. For example, the cable 5 a may be routed outside the inner rail portion 230 .

Also, in this embodiment, an example in which the measurement unit 1 is provided with respect to the inner rail portion 230 via the bracket 280 is shown, but the present invention is not limited to such an aspect. For example, the measurement unit 1 may be provided on the inner rail portion 230 without providing the bracket 280 .

Further, in the present embodiment, an example in which the fixing means 250 is provided on the outer rail portion 220 of the support portion 210 and the measurement unit 1 is provided on the inner rail portion 230 is shown, but the present invention is not limited to such an aspect. do not have. For example, the fixing means 250 may be provided for the inner rail portion 230 and the measurement unit 1 may be provided for the outer rail portion 220 .

In addition, the control unit 290 is installed on the floor (the top floor Fr or the middle floor Fn) where the jig 100 for the top floor or the jig 200 for the intermediate floor is installed, and controls the press-in speed of the concrete 8 and the like. Although the display is made via the monitor installed on the floor (ground floor Fa), the configuration is not limited to this. For example, the control unit 290 may display the press-in speed of the concrete 8, etc., not on the monitor installed on the ground floor Fa, but on the display of a predetermined tablet terminal that can be carried by the worker. Also, the control unit 290 may not be installed on the top floor Fr or the middle floor Fn, but may be configured by the tablet terminal described above.

1 Measurement Unit 4 Laser Rangefinder 7 Steel Pipe 8 Concrete 8a Top 9a Upper Surface 100 Jig for Top Floor 110 Supporting Part 120 Leg 123 Movement Suppressing Means 125 Magnet Part 130 Mounting Part 131 Upper Surface (Mounting Surface)
140 unit holding portion 150 housing portion 157 lower surface (facing surface)
160 angle adjustment means 170 internal position adjustment means

Claims (6)

A jig for supporting a measuring unit having a laser rangefinder for measuring the distance from above a steel pipe for CFT structure to the top of concrete pressed into the steel pipe,
a support portion installed on the installation surface;
a unit holding part supported by the support part above the steel pipe and holding the measurement unit so that the measurement unit faces downward;
a movement suppressing means that contacts the installation surface and suppresses movement of the support portion relative to the installation surface;
and
The support part is
Having a mounting surface on which the unit holding portion is mounted,
The unit holding part is
Having a facing surface facing the mounting surface,
An angle adjusting means capable of adjusting the angle of the unit holding portion with respect to the supporting portion by adjusting the distance between the mounting surface and the facing surface at least three points;
Jig. A jig for supporting a measuring unit having a laser rangefinder for measuring the distance from above a steel pipe for CFT structure to the top of concrete pressed into the steel pipe,
a support portion installed on the installation surface;
a unit holding part supported by the support part above the steel pipe and holding the measurement unit so that the measurement unit faces downward;
a movement suppressing means that contacts the installation surface and suppresses movement of the support portion relative to the installation surface;
and
The unit holding part is
a tubular accommodation portion in which the measurement unit is accommodated;
internal position adjusting means capable of adjusting the position of the measurement unit with respect to the housing section by adjusting the distance between the inner surface of the housing section and the outer surface of the measurement unit at least three points;
comprising a
Jig . The support part is
comprising at least three legs that are vertically extendable;
The jig according to claim 1 or 2. The movement suppressing means is
Having a magnet part that can switch between generation and non-generation of magnetic force,
A jig according to any one of claims 1 to 3. Further comprising a positioning part provided on the installation surface and capable of positioning the support part with respect to the steel pipe,
A jig according to any one of claims 1 to 4. The unit holding section is
a tubular accommodation portion in which the measurement unit is accommodated;
internal position adjusting means capable of adjusting the position of the measurement unit with respect to the housing section by adjusting the distance between the inner surface of the housing section and the outer surface of the measurement unit at least three points;
comprising a
The jig according to claim 1 .

Images