JP2018119372A - Management device of filling type steel pipe concrete column - Google Patents

Abstract

PROBLEM TO BE SOLVED: To safely and easily install a management device while reducing costs.SOLUTION: The present invention is advantageous in that a cable guide mechanism 26 is easily mounted to a steel pipe 12 by adsorbing an adsorption magnet device 48 to an outer peripheral surface of the steel pipe 12 regardless of a shape and size of the steel pipe 12, as a position of an adsorption magnet device 48 can be moved along an extending direction of a lower frame 46. The present invention is also advantageous in that a position or inclination of the horizontal direction or vertical direction of the cable guide mechanism 26 is easily adjusted such that a camera unit 22(case 40) suspended by cable 24 contacts a marginal part of placement hole of a reinforcement plate for the steel pipe 12 to be not caught regardless of the shape and size of the steel pipe 12, as an upper frame 50 can be moved and regulated along the extending direction of the lower frame 46 and an arm support part 54 can be moved and regulated along the extending direction of the upper frame 50.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a management apparatus for filled steel pipe concrete columns.

In the construction of a filled steel pipe concrete column (CFT (Concrete Filled Tube)) that fills the steel pipe with concrete, it is important to accurately control the concrete filling condition.
In Patent Document 1, an illuminating means, an imaging means, a distance measuring means and the like are accommodated and held in a case, and a case introduced from the outside of the steel pipe into the steel pipe through an opening formed in the side wall of the steel pipe is suspended via a cable. A technique for obtaining information on the inside of the steel pipe, for example, image information inside the steel pipe or information on the height of the top of the filled concrete has been proposed.
In this case, it is necessary to install a cable guide mechanism that guides the cable from the opening of the steel pipe into the steel pipe.

Japanese Patent No. 5878799

By the way, when the cable is guided from the upper end opening of the steel pipe to the inside of the steel pipe, when the cable guide mechanism is attached to the side wall of the steel pipe near the upper end opening, the cross-sectional shape (square tube shape or cylindrical shape) or size of the steel pipe is large. Since the length varies, it is necessary to manufacture a cable guide mechanism each time according to the shape and size of the steel pipe.
It is also conceivable to install the cable guide mechanism on a scaffold near the upper end of the steel pipe. Even in this case, it is necessary to manufacture the cable guide mechanism each time according to the positional relationship between the upper end of the steel pipe and the scaffold.
Therefore, there is a disadvantage that the cost required for installing the cable guide mechanism increases.
Moreover, when the upper end of the steel pipe to be managed is located at a high position in the vicinity of the outside of the building, there is room for improvement in installing the cable guide mechanism safely and easily.
The present invention has been made in view of such circumstances, and an object of the present invention is to provide a filled steel pipe concrete column management apparatus that is advantageous for safe and simple installation while reducing costs.

  In order to achieve the above-mentioned object, the present invention is a filled-type steel pipe concrete column management device, in which a detection unit for detecting information inside a steel pipe is accommodated, and a cable for suspending the case inside the steel pipe A cable guide mechanism for guiding the cable from the upper end opening of the steel pipe into the steel pipe, and a cable winding mechanism for raising and lowering the case inside the steel pipe by winding and unwinding the cable, The cable guide mechanism includes a frame-shaped lower frame and an attracting magnet for attaching the lower frame to the steel pipe by being arranged so as to be movable and adjustable along the extending direction of the lower frame and adsorbing to the outer peripheral surface of the steel pipe The device and the lower frame are coupled to each other at positions facing each other so as to be movable and extend upwardly from the positions facing each other. A frame, an arm having a suspension pulley around which the cable is wound at one end in the longitudinal direction, and a suspension pulley provided when movable in the extending direction of the upper frame. And an arm support portion that supports an intermediate portion in the longitudinal direction of the arm in a state of being positioned inside the upper end opening.

According to the present invention, it is advantageous to easily attach the cable guide mechanism to the steel pipe by adsorbing the attracting magnet device to the outer peripheral surface of the steel pipe regardless of the shape and size of the steel pipe.
Also, regardless of the shape and size of the steel pipe, the horizontal direction of the cable guide mechanism, so that the case suspended by the cable does not come into contact with the edge of the hole in the steel pipe reinforcement plate, This is advantageous for easily adjusting the vertical position or inclination.
Therefore, unlike the conventional case, there is no need to manufacture the cable guide mechanism each time according to the shape and size of the steel pipe, which is advantageous in reducing the cost of the cable guide mechanism and the cost required to install the cable guide mechanism. .
In addition, because the cable guide mechanism can be easily attached and the cable guide mechanism can be adjusted in the horizontal and vertical positions or tilts, the upper end of the steel pipe to be managed is located near the outside at the height of the building. Even in such a case, it is advantageous to install the cable guide mechanism safely and easily.

It is explanatory drawing explaining the use condition of the management apparatus which concerns on this Embodiment. (A) is a perspective view which shows the structure of a camera unit, (B) is B arrow directional view of (A). It is a perspective view which shows the state in which the cable guide mechanism was attached to the steel pipe. (A) is a perspective view of a cable guide mechanism, (B) is the elements on larger scale of (A). (A) is a perspective view of a cable winding mechanism, (B) is a B arrow view of (A). It is explanatory drawing which shows the connection relation of the management apparatus which concerns on this Embodiment. It is a block diagram which shows the structure of a personal computer. It is a functional block diagram of the management apparatus which concerns on this Embodiment. It is explanatory drawing which shows an example of the management screen of the management apparatus which concerns on this Embodiment. (A) 1st explanatory drawing which shows the state by which the cable guide mechanism was attached to the outer peripheral surface of a square cylindrical steel pipe, (B) is the state by which the cable guide mechanism was attached to the outer peripheral surface of a square cylindrical steel pipe (C) is explanatory drawing which shows the state by which the cable guide mechanism was attached to the cylindrical steel pipe.

Next, the management apparatus according to the embodiment of the present invention will be described.
First, the construction direction of the filled steel pipe concrete column 10 will be described with reference to FIG.
The filled steel pipe concrete column 10 constitutes a column member of a building structure.
The filled steel pipe concrete pillar 10 is constructed by press-fitting concrete 14 into the internal space of the steel pipe 12 and solidifying it.
The steel pipe 12 used here is a rectangular tube having a length extending over a plurality of floors, and a plurality of reinforcing plates having a placement hole through which the press-fitted concrete 14 passes inside the steel pipe 12. A (diaphragm plate) is fixed at regular intervals over the entire length of the steel pipe 12. In the present embodiment, a plurality of reinforcing plates are provided for each floor.
Furthermore, a concrete pressure inlet 1202 is provided on the side wall of the steel pipe 12 corresponding to each floor. The concrete pressure inlet 1202 is closed by a closing steel plate after the concrete 14 is press-fitted and filled.
In this Embodiment, as shown in FIG. 1, the upper end opening 1203 of the steel pipe 12 protrudes on the floor surface RF of a rooftop.
As shown in FIG. 3, the upper end opening 1203 of the steel pipe 12 is closed by a top plate 1204, and a circular top plate opening 1206 is formed at the center of the top plate 1204. The top plate 1204 is one of a plurality of reinforcing plates.
Such a steel pipe 12 is erected on the foundation 2 constructed on the ground. Then, the concrete 14 is press-fitted and filled into the steel pipe 12 through the concrete pressure inlet 1202 from the concrete pumping pump car 16 carried into the carry-in floor F1 corresponding to the ground floor of the building structure.
Moreover, the beam member is connected to the location corresponding to each floor of the steel pipe 12.

Next, the management apparatus 20 (hereinafter referred to as the management apparatus 20) of the filled steel pipe concrete column 10 of the present embodiment will be described.
In the present embodiment, the floor where the concrete pumping pump 16 or the like is carried into the steel pipe 12 is referred to as a loading floor F1, and the concrete transport pipe of the concrete pumping pump 16 is inserted into the concrete inlet 1202 of the steel pipe 12. The concrete press-in floor to which 1602 is connected is the floors F2 to Fn higher than the carry-in floor F1, and every time the concrete 14 is filled in the steel pipe 12 corresponding to each floor F2 to Fn, the concrete press-in floor is One floor is sequentially transferred to the upper floor.

Moreover, the management apparatus 20 is arrange | positioned on the rooftop.
The management device 20 includes a camera unit 22, a cable 24, a cable guide mechanism 26, a cable winding mechanism 28, a personal computer 30, and the like.

As shown in FIGS. 2A and 2B, the camera unit 22 includes an illumination device 32, an imaging device 34, a laser distance meter 36, a power supply circuit 38 (FIG. 6), and a case 40. Yes.
In this Embodiment, the camera unit 22 comprises the detection part which detects the information inside the steel pipe 12. FIG.

The illumination device 32 functions as illumination means for illuminating the inside of the steel pipe 12.
In the present embodiment, the illumination device 32 is configured by a light emitting diode and is lit by the power supplied from the power supply circuit 38.

The imaging device 34 functions as an imaging unit that images the inside of the steel pipe 12 and generates image information.
The image pickup device 34 picks up an image pickup optical system, an image pickup element that picks up a subject image captured by the image pickup optical system and generates image information, drives the image pickup element, and sends image information sent from the image pickup element to the cable 24. And a signal processing unit that sends it to the personal computer 30 via the.
The imaging device 34 is configured such that the optical axis of the imaging optical system faces downward in the vertical direction with the case 40 suspended from the cable 24.
The imaging device 34 operates with power supplied from the power supply circuit 38.
In addition, the imaging optical system of an imaging device should just be able to monitor the inside of the steel pipe 12 efficiently, and the thing of conventionally well-known various structures can be used.
The imaging optical system has an angle of view of 180 degrees, can capture a range of 360 degrees around the optical axis, and is within a range of 180 degrees around the optical axis in a plane including the optical axis. You may use the fisheye lens comprised so that imaging was possible.
In this case, when the image information obtained by the imaging device is displayed as it is on the display device 30H (FIG. 7) or the like, a distorted image is displayed. Therefore, a natural image that is not distorted by performing a conventionally known image conversion process is displayed. Display it.
Use of such a fisheye lens is advantageous in monitoring the inside of the steel pipe 12 and the state of the concrete 14 placed over a wide range.

The laser distance meter 36 measures the distance in the vertical direction from the top end 14 </ b> A (FIG. 1) of the concrete 14 disposed in the steel pipe 12 and filled in the steel pipe 12, and generates a first distance information. Functions as a measuring means.
The laser distance meter 36 irradiates the top end 14A with laser light, receives the laser light reflected at the top end 14A, and measures the laser distance from the time until the laser light is reflected back at the top end 14A and returned. The distance between the total 36 and the top end 14A is measured, and the measurement result is sent to the personal computer 30 via the cable 24 as first distance information.
The laser distance meter 36 is operated by electric power supplied from the power supply circuit 38.

  The power supply circuit 38 supplies power supplied from the power supply circuit 6002 of the interface unit 60 (FIG. 6), which will be described later, via the cable 24 to the illumination device 32, the imaging device 34, and the laser distance meter 36. is there.

The case 40 is disposed inside the steel pipe 12 so as to be movable up and down, and accommodates and holds the illumination device 32, the imaging device 34, the laser distance meter 36, and the power supply circuit 38.
In the present embodiment, the case 40 has a cylindrical shape with both ends closed, and the inside of the case 40 is sealed. As the material of the case 40, various conventionally known materials such as a metal material having impact resistance and a synthetic resin material can be used.
The upper part of the case 40 is attached to the cable 24 with one end of the cable 24 inserted.
A lower portion of the case 40 is provided with a window 4002 made of a synthetic resin material such as transparent acrylic.
A frame 4004 having a Y-shape in plan view that protects the window 4002 is attached to the outer surface of the window 4002.
The window 4002 is divided into three regions in the circumferential direction by a frame 4004, and the illumination device 32, the imaging device 34, and the laser distance meter 36 are arranged to face each region.

In the present embodiment, the camera unit 22 constituting the detection unit is filled into the steel pipe 12 measured by the laser distance meter 36 and the image information captured by the imaging device 34 as information inside the steel pipe 12. The case where the distance in the vertical direction from the top end 14A (FIG. 1) of the concrete 14 is detected has been described.
However, what is detected as information inside the steel pipe 12 is arbitrary, and the configuration of the detection unit is appropriately determined according to the information inside the steel pipe 12 to be detected.

The cable 24 is introduced from the outside of the steel pipe 12 into the steel pipe 12 through the upper end opening 1203 of the steel pipe 12 and suspends the case 40 (camera unit 22).
In the present embodiment, the cable 24 includes a signal cable that transmits the image information from the imaging device 34 and the first distance information from the laser distance meter 36 to the personal computer 30, the illumination device 32, the imaging device 34, and the laser distance. It functions as a power cable for supplying power from the power circuit 6002 (FIG. 6) to the total 36.
In the present embodiment, the cable 24 also serves as a signal cable and a power cable, but a cable other than the signal cable and the power cable may be provided. In this case, the cable may be any cable that can suspend the case 40 and can be wound and fed by a cable drum 2804 (FIG. 5) described later, and is made of synthetic resin or metal. Various conventionally known suspension members such as wires and wires can be used.

As shown in FIG. 4A, indicators 25 are formed on the surface of the cable 24 at a predetermined reference interval along the extending direction.
The indicator 25 may have any form as long as it can be detected by an indicator detector 58 (FIG. 4A) described later.
For example, the indicator 25 can be formed by printing a line having a uniform width over the circumferential direction of the cable 24 or by applying paint.

As shown in FIGS. 3, 4 </ b> A and 4 </ b> B, the cable guide mechanism 26 guides the cable 24 from the upper end opening 1203 of the steel pipe 12 into the steel pipe 12.
The cable guide mechanism 26 includes an arm 42, a suspension pulley 44A, two intermediate pulleys 44B and 44C, a winding pulley 44D, a lower frame 46, an attracting magnet device 48, an upper frame 50, and an arm support. Part 54.

The arm 42 includes a first arm portion 4202 that extends linearly and a second arm portion 4204 that extends linearly upward from the tip of the first arm portion 4202.
Two mounting brackets 4206 are respectively attached to both sides of the intermediate portion of the first arm portion 4202.
The suspension pulley 44A is rotatably provided at the tip of the second arm portion 4204, and the cable 24 is wound thereon.
The winding pulley 44D is rotatably provided at the base end of the first arm portion 4202, and the cable 24 fed out from the cable winding mechanism 28 is wound thereon.
One intermediate pulley 44B of the two intermediate pulleys 44B and 44C is rotatably provided at the tip of the first arm portion, and the other intermediate pulley 44C is rotatably provided at the intermediate portion of the first arm portion 4202. It has been.
The cable 24 between the suspension pulley 44A and the winding pulley 44D is wound around the intermediate pulleys 44B and 44C.
In FIG. 4B, reference numerals 45A and 45B denote rollers that press the cable 24 toward the intermediate pulley 44C and the winding pulley 44D, respectively.

The lower frame 46 extends in a frame shape, and in the present embodiment, the lower frame 46 has an annular shape.
The lower frame 46 is provided with two semicircular arc-shaped lower guide grooves 4602 extending along the extending direction of the lower frame 46, and these lower guide grooves 4602 penetrate the lower frame 46 in the vertical direction. .
As the shape of the lower frame 46, various conventionally known frame shapes such as a triangular frame, a rectangular frame, a polygonal frame, and an elliptical frame can be used.
However, if the lower frame 46 is formed in an annular shape as in the present embodiment, it is advantageous for smoothly moving the attracting magnet device 48 and the upper frame 50 with a simple configuration.

The attracting magnet device 48 is arranged so as to be movable along the extending direction of the lower frame 46 and is configured to be attracted to the outer peripheral surface of the steel pipe 12.
The attracting magnet device 48 is positioned above the upper end opening 1203 in a state where the lower frame 46 is substantially horizontal, and a part of the lower frame 46 is positioned inside the upper end opening 1203 when viewed in plan. It attaches to the steel pipe 12 in a state.
In the present embodiment, the attracting magnet device 48 includes two coupling portions 4802, a shaft portion 4804, and a magnet portion 4806.
The coupling portion 4802 is coupled to the portions of the lower frame 46 facing each other so as to be movable and adjustable.
In the present embodiment, the coupling portion 4802 has a main body having a bolt (not shown) inserted from above the lower guide groove 4602 of the lower frame 46 and a female screw disposed below the lower frame 46 and screwed into the bolt. And a member 4803.
In the coupling portion 4802, the main body member 4803 is moved along the lower guide groove 4602 with the bolts loosened, and the main body member 4803 is fixed to the lower frame 46 by fastening the bolts.
Constructing the attracting magnet device 48 in this way is advantageous in simplifying the attracting magnet device 48.

The shaft portion 4804 is suspended downward from the main body members 4803 and is rotatably supported by the main body members 4803.
The magnet portion 4806 is supported by the shaft portion 4804 and has a rectangular parallelepiped shape.
The magnet unit 4806 is configured to be switched between an excited state that is attracted to the steel pipe 12 that is a magnetic body and a non-excited state that is not attracted to the steel pipe 12 by rotating the permanent magnet by rotating the knob 4808.

The upper frame 50 is coupled to a portion of the lower frame 46 facing each other so as to be movable, and extends upwardly from the portion of the lower frame 46 facing each other.
In the present embodiment, the upper frame 50 has an upwardly convex semicircular arc shape, and the radius of the upper frame 50 is substantially the same as the radius of the lower frame 46.
An upper guide groove 5002 is formed along the extending direction of the upper frame 50, and the upper guide groove 5002 passes through the upper frame 50.
As the shape of the upper frame 50, various conventionally known frame shapes such as a triangular frame, a rectangular frame, a polygonal frame, and an elliptical frame can be used.
However, when the upper frame 50 has an upwardly convex semicircular arc shape as in the present embodiment, it is advantageous in smoothly moving the arm support portion 54.

Female screws (not shown) are formed at both ends of the upper frame 50 in the longitudinal direction.
A bolt (not shown) inserted into the lower guide groove 4602 of the lower frame 46 from below is screwed into the female screw of the upper frame 50.
Accordingly, the upper frame 50 is moved along the lower guide groove 4602 with the bolts loosened, and the upper frame 50 is fixed to the lower frame 46 by fastening the bolts.

The arm support portion 54 is provided so as to be movable and adjustable in the extending direction of the upper frame 50, and when viewed in plan, the suspension pulley 44 </ b> A is positioned inside the upper end opening 1203, and is an intermediate portion in the longitudinal direction of the arm 42. Is to support.
As shown in FIGS. 3 and 4A, in the present embodiment, the arm support portion 54 includes a pair of mounting brackets 4206 and a pair of connecting pieces 5402.
The pair of connecting pieces 5402 has an elongated shape in the vertical direction, and these connecting pieces 5402 are attached to the bent end portions 4206 </ b> A of the pair of mounting brackets 4206 and are disposed on both sides of the first arm portion 4202.
The upper end of each connecting piece 5402 is attached to the tip bent portion 4206A of the mounting bracket 4206 via a bolt 43A.
A bolt 43B is inserted through the lower end of each connecting piece 5402 and the upper guide groove 5002 of the upper frame 50, and the lower end of each connecting piece 5402 is moved and adjusted along the upper guide groove 5002 via a nut screwed into the bolt 43B. Supported as possible.
That is, by loosening a nut (not shown) screwed into the bolt 43B, movement along the upper guide groove 5002 of each connecting piece 5402 is allowed, and by fastening the nut, the position of each connecting piece 5402 is fixed, That is, the arm 42 is disposed on the upper frame 50 so as to be adjustable.

As shown in FIG. 3, in the cable guide mechanism 26, the suspension pulley 44A provided at the upper end of the second arm portion 4204 is positioned above the upper end opening 1203 of the steel pipe 12, and the first arm portion 4202 is in the horizontal direction. Is attached to the wall portion of the steel pipe 12 via the magnetizing device 48 that is in an excited state so as to be in an extended state.
In this state, the cable 24 is arranged so as to be drawn out and wound up by being wound around the pulleys 44A to 44D.
Therefore, the cable guide mechanism 26 uses the pulleys 44 </ b> A to 44 </ b> D to connect the cable 24 in which the camera unit 22 is suspended with the cable guide mechanism 26 attached to the steel pipe 12 via the lower frame 46 and the upper frame 50. It is a guide that can be fed out and wound up.

As shown in FIG. 4B, the rotary encoder 56 is attached to the first arm portion 4202 via the flexible coupling 57 so as to rotate integrally with the other intermediate pulley 44C.
Therefore, the rotary encoder 56 detects the amount of rotation of the intermediate pulley 44C corresponding to the amount of movement of the cable 24 between the intermediate pulley 44B and the winding pulley 44D, and the rotation amount information as the detection result is detected by the personal computer 30. To supply.
As shown in FIG. 4A, the index detector 58 is attached to the first arm portion 4202. The index detector 58 functions as an index detection unit that detects the index 25 of the cable 24 and supplies index detection information to the personal computer 30. As such an indicator detector 58, various conventionally known sensors such as an optical sensor that irradiates the surface of the cable 24 with detection light and determines the presence or absence of the indicator 25 based on a change in the amount of reflected light can be used.

As shown in FIG. 1, the cable winding mechanism 28 moves the case 40 up and down inside the steel pipe 12 by winding and unwinding the cable 24 via the cable guide mechanism 26.
As shown in FIGS. 5A and 5B, the cable winding mechanism 28 includes a base 2802, a cable drum 2804, a handle 2806, a power transmission unit 2808, and the like.
The base 2802 is fixed to the roof floor FR.
The cable drum 2804 is rotatably supported by the base 2802, and winds and unwinds the cable 24 led out from the cable guide mechanism 26.
The handle 2806 is supported so as to be rotatable with respect to the base 2802.
The power transmission unit 2808 is provided between the handle 2806 and the cable drum 2804, and transmits the rotational force of the handle 2806 to the cable drum 2804, thereby rotating the cable drum 2804 in the winding direction and the feeding direction. As the power transmission unit 2808, various conventionally known mechanisms such as a combination of a toothed belt and a plurality of gears can be used.
The cable drum 2804 is configured such that the rotational position is held by pressing the friction plate. Therefore, after the camera unit 22 is moved to an arbitrary position by rotating the handle 2806, the position of the camera unit 22 is maintained even if the hand is released from the handle 2806.
Accordingly, by rotating the handle 2806 of the cable winding mechanism 28 in the forward / reverse direction, the cable 24 is wound and fed out. As a result, the cable 24 is moved via the cable guide mechanism 26, whereby the camera unit 22 is moved. The steel pipe 12 is moved up and down. Then, by stopping the rotation of the handle 2806, the position of the camera unit 22 is determined.

In the figure, reference numeral 2810 denotes a slip ring provided between the base 2802 and the cable drum 2804 and electrically connected to the cable 24.
An interface unit 60 for connecting the slip ring 2810 and the personal computer 30 is attached to the base 2802.
As shown in FIG. 6, the interface unit 60 includes a power supply circuit 6002, a microcomputer 6004, and a USB interface 6006.
The power supply circuit 6002 functions by power supplied from the AC adapter 62 connected to the commercial power supply, and supplies power to the power supply circuit 38 on the camera unit 22 side via the slip ring 2810 and the cable 24.
The microcomputer 6004 includes first distance information supplied from the laser distance meter 36 via the cable 24 and the slip ring 2810, rotation amount information supplied from the rotary encoder 56, and an index supplied from the index detector 58. The detection information is converted into a format that can be processed by the personal computer 30.
The USB interface 6006 is for performing communication between the microcomputer 6004 and the personal computer 30 by USB.
The image information supplied from the imaging device 34 via the cable 24 and the slip ring 2810 is assumed to be supplied to the personal computer 30 via the microcomputer 6004 and the USB interface 6006. However, image information is provided separately. Distribution to a monitor device or personal computer 30 via a camera server is optional.

As shown in FIG. 1, the personal computer 30 is installed on the floor FR of the rooftop.
As shown in FIG. 7, the personal computer 30 includes a CPU 30A, ROM 30B, RAM 30C, hard disk device 30D, disk device 30E, keyboard 30F, mouse 30G, display device 30H, printer device 30I, input / output interface 30J, and the like. Yes.
The ROM 30B stores predetermined data and programs, and the RAM 30C provides a working area.
The hard disk device 30D stores a control program for realizing the function of the management device 20.

The disk device 30E records and reproduces data on a recording medium such as a CD or a DVD.
In the present embodiment, the data includes image information, the height of the top end 14A, and the like.
The keyboard 30F and the mouse 30G receive operation inputs from the operator.
The display device 30H displays and outputs data.
The printer device 30I prints out data.
The input / output interface 30J exchanges data with the imaging device 34, the laser distance meter 36, the rotary encoder 56, and the index detector 58 via the interface unit 60.

  As shown in FIG. 8, the personal computer 30 implements a display unit 64, a second distance measuring unit 66, and a top height calculating unit 68 by the CPU 30A executing the control program.

The display means 64 displays an image based on the image information supplied from the imaging device 34, and is configured by the CPU 30A and the display device 30H in the present embodiment.
Moreover, the display means 64 shows the ratio of the top height to the total height of the steel pipe 12 based on the top height of the concrete 14 filled in the steel pipe 12 calculated by the top height calculation means 68 in FIG. It is displayed in real time using the figure 70 shown.
In this case, the displayed graphic 70 is one-dimensional as the steel pipe display portion 70A corresponding to the cross-sectional shape of the steel pipe 12 corresponding to the steel pipe 12, the slab display portion 70B corresponding to the slab on each floor, and the top end 14A rising. And a concrete display portion 70C displayed as a bar graph that changes with time.
Therefore, it is advantageous in intuitively grasping the position of the top end 14A.

The second distance measuring means 66 measures the distance in the vertical direction between a predetermined reference position and the laser distance meter 36, and generates second distance information.
In the present embodiment, the reference position is, for example, the position of the base portion 2 (FIG. 1).
In the present embodiment, the second distance measuring unit 66 includes a correcting unit 67 in addition to the rotary encoder 56 and the index detector 58.
The correction unit 67 generates second distance information based on the rotation amount information detected by the rotary encoder 56, that is, the movement amount of the cable 24, and the reference 25 every time the index 25 is detected by the index detector 58. The second distance information is corrected using the interval.

  The top end height calculating unit 68 calculates the height of the top end 14A of the concrete 14 from the reference position based on the first distance information and the second distance information corrected by the correcting unit 67. is there.

In the present embodiment, as shown in FIG. 1, personal computers 72 and 74 are also installed in the concrete press-in floors F2 to Fn and the carry-in floor F1, and the personal computers 72 and 74 and the management apparatus 10 The personal computer 30 is communicably connected via a LAN 76.
The information displayed on the display means 64 of the monitoring device is supplied to the personal computers 72 and 74 on the concrete press-in floors F2 to Fn and the carry-in floor F1 via the LAN 76, so that the other personal computers 72 and 74 are supplied. The display content identical to the display content of the display means 64 of the management apparatus 10 is also displayed.
Further, the LAN 76 is connected to the Internet 78, and the display contents can be distributed to the offices, facilities, and customer personal computers 80, 82, and 84 away from the site via the Internet 78 in the same manner as described above. Has been.

Next, the usage method of the management apparatus 20 of this Embodiment is demonstrated.
First, the cable winding mechanism 28 is installed on the roof floor FR, and the cable guide mechanism 26 is attached to the steel pipe 12 located on the roof floor FR via the lower frame 46 and the upper frame 50. The camera unit 22 is suspended from the upper end opening 1203 via the cable 24. In the present embodiment, the camera unit 22 is suspended from the top plate opening 1206 via the cable 24.
More specifically, first, the cable guide mechanism 26 is attached to the outer peripheral surface of the steel pipe 12 via the lower frame 46 and the upper frame 50 in a state where no cable is wound around the pulleys 44A to 44D.
That is, the lower frame 46 is positioned horizontally above the upper end opening 1203 of the steel pipe 12 and a part of the lower frame 46 is positioned inside the upper end opening 1203 when viewed in a plan view. The position of the magnet portion 4806 is moved along the lower guide groove 4602 so that the magnet portion 4806 of the attracting magnet device 48 is superimposed on the outer peripheral surface of the steel pipe 12.
If the attracting magnet device 48 is superimposed on the outer peripheral surface of the steel pipe 12, each magnet portion 4806 is switched from the non-excited state to the excited state by rotating the knob 4808, so that the attracting magnet device 48 is placed on the outer peripheral surface of the steel pipe 12. Adsorb.
Next, the coupling portion 4802 is fixed to the lower frame 46 by fastening a bolt to the main body member 4803 of the attracting magnet device 48. As a result, the lower frame 46 is fixed to the outer peripheral surface of the steel pipe 12 via the attracting magnet device 48.

  Next, in this embodiment, the upper frame is positioned above the top plate opening 1206 so that the suspension pulley 44A at the tip of the second arm portion 4204 of the arm 42 is positioned above the upper end opening 1203. The movement adjustment along the extending direction of the lower frame 46 of 50 and the movement adjustment along the extending direction of the upper frame 50 of the arm support portion 54 are performed, and the position or inclination of the arm 42 in the horizontal and vertical directions is adjusted. To do. When the upper frame 50 and the arm 42 are adjusted, the positions of the upper frame 50 and the arm 42 are fixed by fastening bolts, respectively.

Next, the cable 24 is wound around the pulleys 44A to 44D, the camera unit 22 (case 40) is inserted into the steel pipe 12 from the upper end opening 1203 of the steel pipe 12, and the handle 2806 of the cable winding mechanism 28 is turned. The cable 24 is drawn out from the cable winding mechanism 28 and the camera unit 22 (case 40) is lowered downward.
At this time, when the camera unit 22 (case 40) suspended by the cable 24 comes into contact with the edge of the top plate opening 1206 or the edge of the hole in the reinforcing plate of the steel pipe 12, Again, the horizontal or vertical position or inclination of the cable guide mechanism 26 is adjusted so that the case 40 does not interfere with the edge of the hole for placing the reinforcing plate.
That is, the bolts fixing the upper frame 50 to the lower frame 46 and the bolts fixing the arm support 54 to the upper frame 50 are once loosened.
Then, movement adjustment along the extending direction of the lower frame 46 of the upper frame 50 and movement adjustment along the extending direction of the upper frame 50 of the arm support portion 54 are performed, and the positions of the arms 42 in the horizontal direction and the vertical direction are adjusted. Alternatively, the inclination is adjusted.
When the upper frame 50 and the arm 42 are adjusted, the positions of the upper frame 50 and the arm 42 are fixed by fastening bolts, respectively.
In this way, by adjusting the position or inclination of the cable guide mechanism 26 in the horizontal and vertical directions, the camera unit 22 can be smoothly moved up and down and the inside of the steel pipe 12 can be monitored efficiently.

When the adjustment of the horizontal or vertical position or inclination of the cable guide mechanism 26 is completed, the handle 2806 of the cable winding mechanism 28 can be turned to image the filling of the concrete 14, and the top end of the laser distance meter 36 can be imaged. The camera unit 22 is lowered to a position where the position can be measured, and the height of the camera unit 22 is determined.
At this time, second distance information is generated by the second distance measuring means 66 based on the amount of movement of the cable 24 detected by the rotary encoder 56, and each time the index 25 is detected by the index detector 58. By correcting the second distance information using the reference interval, the second distance information that is the distance of the laser rangefinder 36 with respect to the reference position can be accurately obtained.
Therefore, even if the intermediate pulley 44C slips with respect to the cable 24 and an error occurs in the rotation amount of the rotary encoder 56 with respect to the movement amount of the cable 24, the second distance information is obtained by correcting the error. Can be obtained accurately.
Accordingly, the height of the top end 14A can be obtained accurately, which is advantageous in accurately managing the height of the top end 14A of the concrete 14.

Next, the ready-mixed concrete is sequentially put into the inlet of the concrete pumping vehicle 16 from the concrete mixer truck that has entered the loading floor F1.
At the same time, the concrete pumping pump 16 is started to press-fit the ready-mixed concrete 14 into the internal space of the steel pipe 12 from the concrete pressure inlet 1202 of the steel pipe 12 through the concrete transport pipe 1602.

When the concrete 14 continues to be press-fitted and filled in the internal space of the steel pipe 12, the top end 14A rises in the internal space as shown by the arrow in FIG.
The laser distance meter 36 measures first distance information, which is the distance to the top end 14A, in real time.
The top edge height calculating means 68 calculates the height of the top edge 14A of the concrete 14 from the reference position in real time based on the first distance information and the second distance information obtained in real time.

A management screen shown in FIG. 9 is displayed on the display device.
On the management screen, (1) image information D1 indicating the situation of the top end 14A inside the steel pipe 12 obtained by the imaging device 34, and (2) the total height of the steel pipe 12 based on the top end height of the concrete 14 A graphic 70 showing the ratio of the top height is displayed.
In the image information, reference numeral 1210 denotes a reinforcing plate formed inside the steel pipe 12, and reference numeral 1212 denotes a placement hole formed in the reinforcing plate.
Therefore, since the ratio of the top end height of the filled concrete 14 to the total height of the steel pipe 12 based on the top end height is displayed in real time using a figure, the height of the top end 14A is intuitive. It is advantageous in grasping.
Further, the graphic is a steel pipe display portion 70A corresponding to the cross-sectional shape of the steel pipe 12, a slab display portion 70B corresponding to the slab on each floor, and a concrete displayed as a bar graph that changes one-dimensionally as the top end 14A rises. Since it is configured with the display unit 70C, the positional relationship between the top end 14A and the slab can be intuitively grasped, which is more advantageous in accurately managing the height of the top end 14A of the concrete 14.

Moreover, as a management screen shown in FIG. 9, a speed graph showing the rising speed of the concrete top height with the passage of time as shown by reference numeral D3, and a concrete top end height with the passage of time as shown by reference numeral D4. You may make it display the height graph which shows a position. These graphs may be generated in real time by the personal computer 30 based on the top height of the concrete 14 calculated by the top height calculation means 68.
Further, an image pickup device is installed on the carry-in floor F1, and image information indicating the state of the carry-in floor F1 captured by the image pickup device is transmitted to the personal computer 30 of the management device 20 via the LAN 76, as indicated by reference numeral D5. In addition, it may be displayed as an image showing the status of the carry-in floor F1.

According to the present embodiment, since the position of the attracting magnet device 48 can be moved along the extending direction of the lower frame 46, the attracting magnet device 48 can be moved regardless of the shape and size of the steel pipe 12. This is advantageous when the cable guide mechanism 26 is easily attached to the steel pipe 12 by being attracted to the outer peripheral surface of the steel pipe 12.
Further, since the upper frame 50 can be moved and adjusted along the extending direction of the lower frame 46, and the arm support portion 54 can be moved and adjusted along the extending direction of the upper frame 50, the shape and size of the steel pipe 12 are concerned. First, the horizontal direction and the vertical direction of the cable guide mechanism 26 are prevented so that the camera unit 22 (case 40) suspended by the cable 24 does not come into contact with the edge of the placement hole of the reinforcing plate of the steel pipe 12 and is caught. This is advantageous for easily adjusting the position or inclination of the direction.
Therefore, unlike the prior art, it is not necessary to manufacture the cable guide mechanism 26 in accordance with the shape and size of the steel pipe 12, and the cost of the cable guide mechanism 26 and the cost required to install the cable guide mechanism 26 are reduced. Is advantageous.
Moreover, since the installation work of the cable guide mechanism 26 and the adjustment work of the horizontal or vertical position or inclination of the cable guide mechanism 26 can be easily performed, the upper end of the steel pipe 12 to be managed is near the outside at the height of the building. Even when the cable guide mechanism 26 is located in the position, it is advantageous to install the cable guide mechanism 26 safely and easily.

In the present embodiment, the attracting magnet device 48 positions the lower frame 46 above the upper end opening 1203 and positions a part of the lower frame 46 inside the upper end opening 1203 when viewed in plan. It attaches to the steel pipe 12 in the made state.
Therefore, it is advantageous to smoothly adjust the movement of the upper frame 50 along the extending direction of the lower frame 46 so that the cable 24 that suspends the camera unit 22 is guided inside the upper end opening 1203.

Further, according to the present embodiment, the arm 42 includes a first arm portion 4202 that extends linearly and whose intermediate portion in the extending direction is supported by the arm support portion 54, and the distal end of the first arm portion 4202. Cable 24 extending from the cable take-up mechanism 28 to the base end of the first arm portion 4202. A winding pulley 44D is provided.
Therefore, the suspension pulley 44 </ b> A and the take-up pulley 44 </ b> D are provided at both ends in the extending direction of the arm 42, and the middle of the extending direction of the arm 42 is supported by the arm support portion 54.
Therefore, the load of the camera unit 22 applied to the suspension pulley 44A and the take-up pulley 44D via the cable 24 is not biased in any one of the extending directions of the arm 42. Applying a load in a balanced manner to the support portion 54 is advantageous for improving the durability of the arm 42 and the arm support portion 54.

Further, according to the present embodiment, an intermediate pulley 44C around which the cable 24 between the suspension pulley 44A and the take-up pulley 44D is wound is provided at the tip of the first arm portion 4202, and the intermediate pulley 44C is provided. The first arm portion 4202 is provided with a rotary encoder 56 that detects the amount of movement of the cable 24 between the winding arm 44D and the winding pulley 44D.
Therefore, the rotary encoder 56 can be disposed using the limited space of the arm 42, which is advantageous in saving the space of the cable guide mechanism 26.

In the present embodiment, the case where the rotary encoder 56 is provided on the arm 42 has been described. However, the rotary encoder only needs to be able to detect the amount of movement of the cable 24, and the installation location is not limited.
For example, you may provide a rotary encoder in the base 2802 of the cable winding mechanism 28 as follows.
That is, a pulley wound around the cable 24 that is fed out or wound up from the cable drum 2804, a flexible coupling that rotates integrally with the pulley, and a rotary that rotates integrally with the pulley via the flexible coupling. An encoder is provided on the base 2802.
In this case, since the rotary encoder can be arranged using the dead space of the base 2802, it is advantageous in simplifying the cable guide mechanism 26 and saving space.

Further, in the present embodiment, as shown in FIG. 10A, the steel pipe 12 has a rectangular tube shape, and the cable guide mechanism 26 has the lower frame 46, the attracting magnet device 48, and the upper frame 50 in a plan view. The case where it was attached to one side surface of the four side surfaces of the steel pipe 12 via the above has been described.
However, since the lower frame 46 extends in a frame shape and the upper frame 50 extends upward in a convex shape, as shown in FIG. 10B, the cable guide mechanism 26 is connected to the steel pipe in a plan view. It can also be attached to 12 corners.
In this case, the two magnet portions 4806 of the attracting magnet device 48 are attracted to two side surfaces sandwiching the corner portion of the steel pipe 12, respectively.
Further, since the lower frame 46 extends in a frame shape and the upper frame 50 extends in a convex shape upward, even if the steel pipe 12 is a cylinder as shown in FIG. The cable guide mechanism 26 can be attached to the outer peripheral surface of the steel pipe 12.
Thus, the cable guide mechanism 26 can be attached to the steel pipe 12 regardless of the cross-sectional shape of the steel pipe 12.

DESCRIPTION OF SYMBOLS 10 Filling type steel pipe concrete pillar 12 Steel pipe 1203 Upper end opening 14 Concrete 20 Management apparatus 22 Camera unit (detection part)
24 cable 26 cable guide mechanism 28 cable take-up mechanism 2802 base 2804 cable drum 40 case 42 arm 44A suspension pulley 44B intermediate pulley 44C intermediate pulley 44D take-up pulley 46 lower frame 48 attracting magnet device 4802 coupling portion 4804 shaft Part 4806 magnet part 50 upper frame 54 arm support part 56 rotary encoder (encoder)

Claims (8)

A management device for filled steel pipe concrete columns,
A case in which a detector for detecting information inside the steel pipe is housed;
A cable for suspending the case inside the steel pipe;
A cable guide mechanism for guiding the cable from the upper end opening of the steel pipe into the steel pipe;
A cable winding mechanism for lifting and lowering the case inside the steel pipe by winding and unwinding the cable;
The cable guide mechanism is
A frame-like lower frame;
An attracting magnet device for attaching the lower frame to the steel pipe by adhering to the outer peripheral surface of the steel pipe arranged so as to be movable and adjustable along the extending direction of the lower frame;
An upper frame that is coupled to the opposite positions of the lower frame so as to be movable and extends upwardly from the opposed positions;
An arm having a suspension pulley around which the cable is wound at one end in the longitudinal direction;
An arm support portion that is provided so as to be movable and adjustable in the extending direction of the upper frame, and that supports the intermediate portion in the longitudinal direction of the arm in a state where the suspension pulley is positioned inside the upper end opening. When,
An apparatus for managing a filled steel pipe concrete column, comprising: The lower frame has an annular shape,
The filled steel pipe concrete column management device according to claim 1. The upper frame has a semicircular arc shape,
3. The filled steel pipe concrete column management device according to claim 1 or 2, wherein: The attracting magnet device includes two coupling portions coupled to each other in the lower frame so as to be movable, and shafts that are suspended downward from the coupling portions and rotatably supported by the coupling portions. And a rectangular parallelepiped magnet supported by the shaft portion,
The filled steel pipe concrete pillar management device according to any one of claims 1 to 3. The arm extends linearly and has a first arm portion in which an intermediate portion in the extending direction is supported by the arm support portion; and the tip extends linearly upward from the tip of the first arm portion. And a second arm portion provided with the suspension pulley.
A winding pulley around which the cable fed out from the cable winding mechanism is wound is provided at the proximal end of the first arm portion.
The filled steel pipe concrete pillar management device according to any one of claims 1 to 4. An intermediate pulley around which a cable between the suspension pulley and the take-up pulley is wound is provided at the tip of the first arm portion,
An encoder for detecting a movement amount of the cable between the intermediate pulley and the winding pulley is provided in the first arm portion;
The filled steel pipe concrete column management device according to claim 5. The cable winding mechanism includes a cable drum that winds and unwinds the cable, and a base that rotatably supports the cable drum,
An encoder for detecting the amount of movement of the cable wound around the cable drum or fed out from the cable drum is provided on the base.
The filled steel pipe concrete pillar management device according to any one of claims 1 to 5. The attracting magnet device is attached to the steel pipe in a state where the lower frame is positioned above the upper end opening and a part of the lower frame is positioned inside the upper end opening when viewed in plan. ,
The management apparatus for filled steel pipe concrete columns according to any one of claims 1 to 7.

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