JP2018123608A - Hanging-down removal device of tunnel ceiling part concrete matter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hanging-down removal device of a tunnel ceiling part concrete matter that facilitates operation of elevating the concrete matter, and can secure sufficient bearing capacity without damaging the tunnel.SOLUTION: A hanging-down removal device of a tunnel ceiling part concrete matter comprises a support frame 30 that is installed on an existing concrete matter 21 and movable to a connecting direction X of the concrete matter 21, hoist units 31 that can hang up the concrete matter 21 or hang down the same, and a rotation jig 32 that rotationally supports the hung-down concrete matter 21. The support frame 30 comprises a pair of support body parts 30a that have an arch shape and are spaced on the connecting direction X, where both end parts 30c are disposed to both end parts 21b of the existing concrete matter 21, and connection support beam parts 30b that connect with these support body parts 30a by extending to the connecting direction X on an upper surface of the support body parts 30a, where the hoist units 31 is mounted.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a mechanism for suspending and removing a tunnel ceiling concrete slab, and in particular, suspending a tunnel ceiling concrete slab that is used when an existing concrete slab forming a tunnel ceiling slab is sequentially suspended and removed. It relates to the removal mechanism.

  In existing tunnels with a horseshoe shape or a circular cross-sectional shape that includes an arc-shaped cross-section at the top, the upper part is partitioned by a ceiling plate to form a flat ceiling surface, and an arc-like shape above the ceiling plate There are many cases where a hollow part having an arcuate cross-sectional shape between it and the cross-sectional part can be used as a space for ventilation, a space for piping and wiring, etc. In some tunnels, the ceiling slab may be removed due to the aging of the ceiling slab and the change of the ventilation system.

  The tunnel slab of such a tunnel is a concrete made of precast concrete, which is manufactured in advance in a factory or the like and has a horizontal rectangular planar shape having the same length as the horizontal width of the tunnel at the position where the ceiling slab is installed. The plate is formed by arranging a plurality of plates in a continuous direction along the axial direction of the tunnel, with both ends of the plate supported by a support member provided to extend inward from the side wall of the tunnel. Yes.

  In addition, as a method of removing the concrete plate forming the ceiling plate of such an existing tunnel, for example, using a multi-axis transport vehicle that is a mobile special vehicle equipped with a lifting platform with a jack, while supporting from below A method has been developed in which concrete plates arranged continuously along the axial direction of the tunnel are sequentially removed from those located at the front end in the connecting direction (see, for example, Patent Document 1).

JP 2016-1442098 A

  However, in the method of removing the concrete plates that are installed continuously while supporting them from below by a movable special vehicle equipped with a lifting platform with a jack, the control for raising and lowering while supporting the concrete plates, which are heavy objects, in good balance In particular, since the road surface of the tunnel where the special vehicle moves has a longitudinal gradient and a transverse gradient, the control for raising and lowering the concrete plate while supporting it in a balanced manner becomes more difficult.

  A method of removing the concrete plate while lifting it from above using a mobile crane is also conceivable. However, since the size of the space above the ceiling plate and the top surface of the tunnel is limited, the crane It is difficult to arrange a boom such as above the concrete plate, it is difficult to secure a sufficient suspension allowance, and when the concrete plate is lifted or lowered, the boom or concrete plate is an existing structure. Therefore, it takes a lot of time and effort to avoid contact.

  In addition, for example, a hoist crane may be used as a simple lifting device that can secure a considerable lifting allowance even in a narrow space, but when using a hoist crane, the steel material that supports the hoist crane is fixed. It will be necessary to drive the anchor member into the top surface of the tunnel to damage the top surface of the tunnel, and it is sufficient to fix the steel by simply driving the anchor member into the top surface of the tunnel. It becomes difficult to secure the supporting force.

  The present invention lifts the concrete plate to be removed from above, thereby facilitating the operation of raising and lowering the concrete plate in a well-balanced manner and ensuring sufficient support without damaging the top surface of the tunnel. An object of the present invention is to provide a mechanism for hanging and removing a concrete plate of a tunnel ceiling.

  The present invention provides an existing concrete plate for forming a ceiling plate of a tunnel, in which a support member provided so as to project inward from a side wall portion of the tunnel is supported at both ends and arranged in a continuous manner in a continuous direction. Is a mechanism to suspend and remove the tunnel ceiling concrete slab used when suspending and removing the concrete slab from the concrete slab on the tip side in the continuous direction. A support frame movable in the connecting direction, a lifting device attached to the support frame and capable of lifting and suspending a concrete plate to be removed, and suspended from the lifting device. A rotating jig that rotatably supports the concrete plate to be removed, and the support frame has an arch shape, and both ends are both ends of the existing concrete plate. At least a pair of support main body portions provided at intervals in the connecting direction, and these support main body portions provided in the upper direction of the support main body portions so as to extend in the connecting direction. And the above-described object is achieved by providing a mechanism for suspending and removing the tunnel ceiling concrete plate that includes the connecting support beam portion to which the lifting device is attached. .

  In the tunnel ceiling concrete plate suspension / removal mechanism according to the present invention, the connection support beam portion is further extended to the front end side from the support main body portion provided at the front end portion in the connecting direction. The lifting / lowering device can be attached so as to be movable in the connecting direction along the protruding portion of the connection support beam portion.

  Further, according to the tunnel ceiling concrete plate hanging and removing mechanism of the present invention, a pair of the connection support beam portions are provided at the same height position in the support main body portion, and each of the connection support beam portions is provided. Further, it is preferable that the lifting device is attached.

  Furthermore, the tunnel ceiling concrete plate suspension / removal mechanism of the present invention comprises an upper beam portion on which the rotary jig is suspended from the lifting device, and a lower beam portion on which the concrete plate to be removed is suspended, Preferably, the lower beam portion is rotatably connected to the upper beam portion, so that the suspended concrete plate to be removed is rotated with respect to the upper beam portion.

  Furthermore, in the tunnel ceiling concrete plate suspension / removal mechanism of the present invention, it is preferable that wheel members are respectively attached to both ends of the support main body.

  The tunnel ceiling concrete plate suspension / removal mechanism according to the present invention prevents both end portions of the support main body portion from being shifted outward at both ends of the concrete plate, and the continuous installation of the support gantry. It is preferable that the slip prevention guide members for guiding the movement in the direction are provided so as to extend along the continuous direction.

  Furthermore, in the suspension ceiling concrete removing mechanism of the tunnel ceiling part according to the present invention, a spacing member for connecting both end portions of each of the support main body portions to each other is disposed at the lower end portion of the support frame. It is preferable.

  According to the tunnel ceiling concrete plate suspension and removal mechanism of the present invention, the concrete plate to be removed is lifted from above, thereby facilitating the operation of raising and lowering the concrete plate in a well-balanced manner. Sufficient support force can be ensured without damaging the surface portion.

The structure of the suspension removal mechanism of the tunnel ceiling part concrete plate which concerns on preferable 1st Embodiment of this invention is demonstrated, (a) is a schematic horizontal cross-sectional view of a tunnel, (b) is a schematic vertical cross-section inside a tunnel. FIG. 2C is a schematic cross-sectional view inside the tunnel. It is the A section enlarged view of Drawing 1 (a). (A) is a schematic cross-sectional view of a tunnel in which a ceiling slab is removed by a suspension and removal mechanism for a tunnel ceiling concrete slab according to a preferred first embodiment of the present invention, and (b) is a portion of the ceiling slab. It is the schematic plan view seen from the top. The process of removing a concrete board | plate using the suspension removal mechanism of the tunnel ceiling part concrete board which concerns on preferable 1st Embodiment of this invention is demonstrated, (a) is a schematic illustration cross section of a tunnel, (b) is shown. A schematic vertical cross-sectional view inside the tunnel, (c) is a schematic cross-sectional view inside the tunnel. The process of removing a concrete board | plate using the suspension removal mechanism of the tunnel ceiling part concrete board which concerns on preferable 1st Embodiment of this invention is demonstrated, (a) is a schematic illustration cross section of a tunnel, (b) is shown. A schematic vertical cross-sectional view inside the tunnel, (c) is a schematic cross-sectional view inside the tunnel. It is the B section enlarged view of Drawing 5 (a). The process of removing a concrete board | plate using the suspension removal mechanism of the tunnel ceiling part concrete board which concerns on preferable 1st Embodiment of this invention is demonstrated, (a) is a schematic illustration cross section of a tunnel, (b) is shown. A schematic vertical cross-sectional view inside the tunnel, (c) is a schematic cross-sectional view inside the tunnel. The process of removing a concrete board | plate using the suspension removal mechanism of the tunnel ceiling part concrete board which concerns on preferable 1st Embodiment of this invention is demonstrated, (a) is a schematic illustration cross section of a tunnel, (b) is shown. A schematic vertical cross-sectional view inside the tunnel, (c) is a schematic cross-sectional view inside the tunnel. The structure of the suspension removal mechanism of the tunnel ceiling part concrete plate which concerns on preferable 2nd Embodiment of this invention is demonstrated, (a) is a schematic horizontal cross-sectional view of a tunnel, (b) is a schematic vertical cross-section inside a tunnel. FIG. 2C is a schematic cross-sectional view inside the tunnel. A step of removing a concrete plate using a suspension and removal mechanism for a tunnel ceiling concrete plate according to a second preferred embodiment of the present invention will be described, (a) is a schematic cross-sectional view of the tunnel, (b) is A schematic vertical cross-sectional view inside the tunnel, (c) is a schematic cross-sectional view inside the tunnel. A step of removing a concrete plate using a suspension and removal mechanism for a tunnel ceiling concrete plate according to a second preferred embodiment of the present invention will be described, (a) is a schematic cross-sectional view of the tunnel, (b) is A schematic vertical cross-sectional view inside the tunnel, (c) is a schematic cross-sectional view inside the tunnel. A step of removing a concrete plate using a suspension and removal mechanism for a tunnel ceiling concrete plate according to a second preferred embodiment of the present invention will be described, (a) is a schematic cross-sectional view of the tunnel, (b) is A schematic vertical cross-sectional view inside the tunnel, (c) is a schematic cross-sectional view inside the tunnel.

  The tunnel ceiling concrete plate suspension / removal mechanism 10 according to the first preferred embodiment of the present invention is an existing road having a ceiling plate 20 provided on the upper portion, as shown in FIGS. As a tunnel 50, in a road tunnel having a horseshoe-shaped cross-section including an arc-shaped cross-section at the top, for example, the ceiling plate 20 is aged, or the ventilation system is changed using a space above the ceiling plate 20. Accordingly, when it becomes necessary to remove the ceiling slab 20, a precast concrete concrete slab 21, which is continuously provided in the axial direction of the road tunnel 50 to form the ceiling slab 20, is installed in the continuous installation direction X. It was adopted as a mechanism that enables efficient removal from the one arranged on the front end side. The tunnel ceiling concrete plate suspension / removal mechanism 10 according to the first embodiment facilitates the operation of lifting and lowering the concrete plate 21 to be removed while supporting it in a well-balanced manner. It has a function to ensure a sufficient supporting force when the concrete plate 21 is raised and lowered without damaging the top surface.

  Then, the tunnel ceiling concrete plate suspension / removal mechanism 10 according to the first embodiment supports both ends of the road tunnel 50 by, for example, supporting members 22 provided so as to project inward from the side wall 51, thereby connecting the both ends. The existing concrete slab 21 forming the ceiling slab 20 of the road tunnel 50 arranged in a row in the installation direction X is successively suspended from the concrete slab 21 on the tip side in the connection direction X and removed. 1A to 1C, a support mechanism 30 that is installed on an existing concrete plate 21 that is continuously provided and is movable in the continuous direction X, as shown in FIGS. The concrete plate 21 attached to the support frame 30 and capable of lifting and suspending the concrete plate 21 to be removed and the concrete plate 21 to be removed from the lift device 31 and suspended from the elevator device 31 are provided. It is configured to include a rotary jig 32 for rolling movably supported. The support frame 30 is provided with an arch shape, and at least a pair (in the first embodiment, spaced apart in the connecting direction X) in which both end portions 30c are disposed at both end portions 21b of the existing concrete plate 21. A pair of support main body portions 30a and upper portions of the support main body portions 30a that extend in the connecting direction X, connect the support main body portions 30a, and have an elevating device 31 attached thereto. And the connected support beam portion 30b.

  In the first embodiment, a pair of connection support beam portions 30b are provided at the same height position in the support main body portion 30a, and the lifting device 31 is attached to each connection support beam portion 30b. Yes.

  Furthermore, in the first embodiment, the rotary jig 32 includes an upper beam portion 33 that is suspended from the lifting device 31 and a lower beam portion 34 that suspends the main body portion 21a of the concrete plate 21 to be removed. Since the part 34 is rotatably connected to the upper beam part 33 via the rotary connecting part 34 a, the suspended concrete plate 21 to be removed can be rotated with respect to the upper beam part 33. (See FIG. 7A).

  In this 1st Embodiment, as shown to Fig.3 (a), (b), the ceiling plate 20 removed by the suspension removal mechanism 10 of a tunnel ceiling part concrete plate was manufactured in the factory etc. previously, It is formed by arranging a number of precast concrete concrete slabs 21 in a continuous arrangement direction X along the axial direction of the road tunnel 50. The concrete plate 21 has, for example, a short side with a length of about 1500 mm, for example, and a long side with a length of, for example, 8000 mm as a length similar to the lateral width of the road tunnel 50 at the height position where the ceiling plate 20 is installed. It has a horizontally long rectangular planar shape. The concrete plate 21 is provided so as to extend from the side wall portion 51 of the road tunnel 50 to the inside, and a support member 22 described later supports both end portions 21b in the long side direction, and the short side direction as the continuous direction X. A large number of the long side portions are arranged and arranged in a state where they are in contact with each other. In addition, the concrete plates 21 arranged in series are arranged in a direction in which a plurality of concrete plates 21 are arranged by a known method using, for example, a PC steel wire, a connecting steel rod, a connecting bolt or the like (not shown). X is provided in an appropriately integrated state.

  As shown in FIG. 2, the support member 22 that supports both ends of the concrete plate 21 in the long side direction is formed by appropriately processing a known steel material such as an H-shaped steel, and is used for a known road tunnel. A bracket member can be used. The bracket member 22 includes a joining base portion 22a having a curved outer peripheral surface shape along the arc-shaped cross-sectional shape of the side wall portion 51 of the road tunnel 50, and a cradle portion 22b provided to project inward from the joining base portion 22a. And formed. In the state where the outer peripheral surface of the bonding base portion 22a is in close contact with the inner surface of the side wall portion 51 of the road tunnel 50 at the height position where the ceiling slab 20 is installed, for example, a bonding fixing bolt (not shown), By fastening toward the side wall 51, the bracket member 22 can be firmly joined and fixed to a predetermined position of the side wall 51 of the road tunnel 50 with the receiving portion 22 b projecting inward. To do.

  In this embodiment, as shown in FIGS. 3A and 3B, the bracket member 22 is arranged at a predetermined height position in the side wall portions 51 on both sides of the road tunnel 50 in the continuous direction X of the concrete plate 21. Along the axial direction of a certain road tunnel 50, the pitch is similar to the length of the short side of the concrete plate 21, and is attached to each of a plurality of locations at intervals, and both ends of the concrete plate 21 are attached to these receiving portions 22b. By placing the portion 21b, a large number of concrete plates 21 can be supported from below.

  The receiving portion 22b of the bracket member 22 includes a flat placement surface 22c for placing the end portion of the concrete plate 21 (see FIG. 2), and the placement surface 22c has a size of about 400 mm in length and width, for example. And a rectangular (square) planar shape (see FIG. 3B). Each concrete plate 21 is attached to the receiving portion 22b of each bracket member 22 by placing the end corners of each adjacent pair of concrete plates 21 in a region obtained by dividing the placement surface 22c into two parts. It has been. As a result, each of the concrete slabs 21 is placed on the receiving portion 22b of the four bracket members 22 from the four corners of the corners, so that the four bracket members 22 from the bottom can be viewed from below. Supported and mounted in a stable state. Each concrete plate 21 is firmly fixed to the bracket member 22 by fastening the fixing anchor 23 toward the receiving portion 22b at the four corners of the end portion placed on the placement surface 22c. ing.

  As described above, the support gantry 30 constituting the tunnel ceiling concrete plate suspension / removal mechanism 10 according to the first embodiment is a pair of supports provided at intervals in the connecting direction X of the concrete plate 21. The main body part 30a, the connection support beam part 30b which connects these support main body parts 30a, and the raising / lowering apparatus 31 attached to the connection support beam part 30b are provided. Each of the pair of support main body portions 30a has, for example, an arch shape such that an H-shaped steel of H-200 has a curved shape along the arc-shaped curved shape of the upper inner surface of the road tunnel 50 having a horseshoe-shaped cross-sectional shape. It is formed by bending. To each arch-shaped support main body 30a, steel corner piece members 38 are integrally attached to both end portions 30c, which are also lower end portions, by welding or the like.

  As shown in FIG. 2, the corner piece member 38 joined to both ends 30c of the support body 30a has a predetermined angle with respect to the horizontal direction at the joint surface with both ends 30c of the support body 30a. It is formed as follows. Since the corner piece member 38 is joined to the both end portions 30c of the support main body portion 30a, the support pedestal 30 applies the load applied from the support main body portion 30a to the horizontal and vertical loads at the both end portions 30c. Can be distributed to both end portions 21b of the concrete plate 21.

  Further, in the first embodiment, the wheel member 37 for movement, preferably made of a known chill tank, is joined to the lower end surfaces of the corner piece members 38 at both end portions 30c of the respective support main body portions 30a. It is attached as a unit. When the wheel member 37 is attached to both end portions 30c of each support main body 30a, when the support pedestal 30 is moved in the connecting direction X of the concrete plate 21 together with the lifting device 31 and the rotary jig 32, For example, it can be moved smoothly even if it is pushed by the power of the worker.

  The connection support beam portion 30b for connecting the pair of support main body portions 30a is made of, for example, an I-shaped steel having a height of about 300 mm, and the end portion of the upper end flange portion is connected to the upper inner circumference of each support main body portion 30a. By joining to the surface by welding or the like, it is arranged so as to straddle the pair of support main body portions 30a, extends in the connecting direction X of the concrete plate 21, and in a state where these support main body portions 30a are connected. It is attached. In the first embodiment, a pair of coupled support beam portions 30b are provided in parallel at the same height position on the upper portion of the support body portion 30a, and a lifting device is provided on the coupled support beam portions 30b. 31 is attached to each. As a result, the support main body 30a of the concrete plate 21 to be removed can be suspended and suspended from the support frame 30 via the lifting device 31 in a more stable state.

  In addition to the connection support beam part 30b attached to the upper part of the pair of support main body parts 30a, for example, the support main body parts 30a are connected to each other in a state of being spaced apart from the lower end part and other parts. By attaching a connecting member (not shown), the support frame 30 can be formed more firmly and integrally.

  The lifting / lowering device 31 attached to the connection support beam portion 30b of the support frame 30 is made of, for example, a known hoist crane, and slides in the connecting direction X of the concrete plate 21 along the connection support beam portion 30b via the traveling device 31a. In a movable state, it is disposed below the lower end flange portion of the connection support beam portion 30b and provided on each of the pair of connection support beam portions 30b. A rotating jig 32 is provided below the pair of lifting devices 31 so as to be suspended from these lifting devices 31 via fishing wires 31b.

  As described above, the rotary jig 32 includes the upper beam portion 33 suspended from the pair of lifting devices 31 and the main body portion 21a of the concrete plate 21 to be removed via the fishing wire 31b (see FIG. 1A). And a lower beam portion 34 for suspending. The upper beam portion 33 is formed of, for example, a rectangular steel pipe having a rectangular hollow cross-sectional shape, and is lifted along the long side direction of the concrete plate 21 perpendicular to the continuous direction X of the concrete plate 21. It is suspended from 31. The lower beam portion 34 is formed of a rectangular steel pipe having a rectangular hollow cross-section, for example, similar to the upper beam portion 33, and is rotatable to the upper beam portion 33 via a rotation connecting portion 34a having a vertical direction as a rotation axis. It is connected. Since the lower beam portion 34 is rotatably connected to the upper beam portion 33, the rotary jig 32 can rotate the suspended concrete plate 21 to be removed with respect to the upper beam portion 33. It has become.

  In the first embodiment, as shown in FIG. 2, both end portions 30c of the support main body portion 30a are shifted to the outside as shown in FIG. 2 at both end portions 21b of the concrete plates 21 that are continuously arranged to form the ceiling plate 20. Each of the anti-slip guide members 36 for preventing and guiding the movement of the support frame 30 in the connecting direction of the concrete plate 21 extends along the connecting direction X.

  The slip guide member 36 is made of, for example, L-shaped steel, and is disposed so as to extend in the connecting direction X of the concrete plate 21 at both ends 21b of the concrete plate 21, and at a predetermined interval in the extending direction. The anchor member 36a is fastened to the concrete plate 21 to be firmly fixed to both end portions 21b of the concrete plate 21. For example, the outer side surface of the corner piece member 38 joined to the both ends 30c of the support main body 30a is brought into contact with and locked to the standing side portion of the L-shaped steel forming the slip prevention guide member 36, or the wheel member The outer portion of 37 can be abutted and locked by interposing a buffer member 37a made of steel or rubber. Thus, as will be described later, when the main body portion 21a of the concrete plate 21 is suspended from the support frame 30, the wheel members 37 attached to both end portions 30c of the support main body portion 30a are replaced with the main body portion 21a of the concrete plate 21. It is possible to effectively avoid shifting to the outside by widening the distance by the weight of the wheel and guiding the wheel member 37 so that the support frame 30 is connected in the direction in which the concrete plate 21 is arranged. It becomes possible to move to X more smoothly.

  Moreover, in this 1st Embodiment, when the main-body part 21a of the concrete plate 21 is suspended from the support stand 30, the wheel member 37 attached to the both ends 30c of the support main-body part 30a makes a space | interval widen. An interval holding member 39 for connecting both end portions 30c of each support main body portion 30a to each other can be provided at the lower end portion of the support frame 30 so as to avoid being displaced outward. . As the spacing member 39, a tie rod, which is a known tensile reinforcement steel material, can be used. As shown in FIG. 2, for example, the corners attached to the both ends 30c of the support main body 30a can be used. It is possible to effectively avoid the wheel member 37 from being displaced outward by being fastened to the outer surface of the piece member 38.

  According to the tunnel ceiling concrete plate suspension / removal mechanism 10 of the first embodiment having the above-described configuration, for example, a pedestal installation step (see FIGS. 4A to 4C) described later, and concrete plate cutting. Steps (see FIGS. 5A to 5C), main body hanging steps (see FIGS. 7A to 7C), and both end removal steps (see FIGS. 8A to 8C) ), And a number of concrete plates 21 forming the ceiling plate 20 can be sequentially suspended and removed.

  In the pedestal installation process, the support pedestal 30 to which the lifting device 31 is attached is placed on both ends 30c on both ends 21b of the concrete plate 21, and the existing ceiling to be removed is movable in the continuous direction X. Install on the plate 20. That is, in the gantry installation process, the support gantry 30 and the lifting / removing mechanism 10 are illustrated in a state where the cradle is disassembled into components having a size and weight that can be assembled manually by a worker using a simple device such as a winch. 4 (a) to 4 (c), the transport vehicle 55 transports the road tunnel 50 to the construction site, and the transported support frame 30 and the components of the suspended removal mechanism 10 are, for example, small cranes. It is lifted using 56 and conveyed onto the existing ceiling slab 20 to be removed. In addition, other necessary devices and equipment such as a concrete cutter device 35 and a winch as a cutting device, which will be described later, are similarly lifted by using, for example, a small crane 56 and transferred onto an existing ceiling plate 20 to be removed. To do.

  After that, by the work on the existing ceiling slab 20, the worker can use the above-described configuration from the disassembled support base 30 and the constituent members of the suspension removal mechanism 10 using the transported apparatus and equipment. Assembling the support frame 30 and the suspension removal mechanism 10 provided with the above.

  In the concrete plate cutting step, as shown in FIGS. 5A to 5C and FIGS. 6A and 6B, the concrete plate 21 at the front end in the connecting direction X is moved from the support frame 30 to the lifting device 31. In the state where the support plate 30 is supported, the cutting lines 40 are respectively formed by the cutting device 35 inside the both end portions 21b on which the support frame 30 is placed in the both end portions 20c of the concrete plate 21. The main body portion 21a is cut off from both end portions 20c.

  That is, in the concrete plate cutting step, an anchor (not shown) is driven into a predetermined position of the main body portion 21a between the both end portions 21b of the concrete plate 21 at the front end portion in the connecting direction X. The concrete plate 21 is supported from the support main body 30a of the support base 30 via the lifting device 31 and the rotary jig 32 by locking the lower end of the suspension wire 34b attached to the lower beam part 34 of the rotary jig 32. It will be in the state. In this state, as a cutting device, for example, a known concrete cutter device 35 as a device for cutting concrete is used, and the connecting direction X is set to the inner portions of the both ends 20b of the both ends 20c of the concrete plate 21 at the tip. A cutting line 40 that extends to the concrete plate 21 and penetrates in the thickness direction is formed. As a result, the main body portion 21a sandwiched between the cutting lines 40 on both sides can be separated from the both end portions 20c.

  Here, in the concrete plate cutting step, it is preferable to form the cut surfaces 40a by the cutting lines 40 of the both end portions 21c of the concrete plate 21 so as to incline outwards downward (see FIG. 4A). . Thereby, in the main body part hanging step described later, the main body part 21a between these, which is separated from the remaining both end parts 20c by the cutting line 40 and is sandwiched by the cutting surface 40a by the cutting line 40, is left. It is possible to smoothly hang down from the both end portions 20c with smooth separation. The cutting surface 40a which inclines outward toward the lower side inclines the concrete cutter device 35 by attaching an inclined biting member 41 on the concrete plate 21, for example, when cutting both end portions 21c of the concrete plate 21. It can be easily formed by moving the concrete cutter device 35 with the cutter blade 35a inclined toward the outside.

  In the main body hanging process, as shown in FIGS. 7A to 7C, the lifting and lowering device 31 is provided with the main body portion 21 a of the concrete plate 21 separated from the both end portions 21 c in a state where the both end portions 21 c are left. To hang down.

  That is, in the main body portion hanging step, the main body portion 21a of the concrete plate 21 separated from the both end portions 21c is supported while being hung from the supporting main body portion 30a of the support frame 30 and supported by the above-described concrete plate cutting step. Then, the lifting device 31 such as a hoist crane attached to the support frame 30 is operated to hang down together with the rotary jig 32.

  Here, in the main body hanging process, the both ends 21c of the concrete plate 21 are left and only the main body 21a is hung downward, so that the road tunnel 50 has a horseshoe-shaped cross section, Even if the tunnel width in the lower portion is narrower than the upper tunnel width to which the plate 21 is attached, both ends of the main body portion 21a to be hung are caught on the side wall portion of the road tunnel 50. Thus, the main body portion 21a can be smoothly suspended.

  Further, in the main body hanging process, the separated main body portion 21 a is moved from the lower beam portion 34 of the rotary jig 32 to the upper beam portion 33 in a space region below the both end portions 21 c left in the road tunnel 50. By rotating with respect to it (see FIG. 7A), preferably, the longitudinal direction L thereof is smoothly rotated and moved along the continuous direction X, and is then suspended downward. . As a result, a trailer or the like in which the vertically long loading platform 57 a is extended in the continuous direction X of the concrete plate 21, which is the axial direction of the road tunnel 50, and is moved directly below the support frame 30 inside the road tunnel 50. The body portion 21a of the concrete plate 21 that is suspended and removed from the loading platform 57a of the unloading vehicle 57 can be smoothly loaded and unloaded.

  When the main body portion 21 a of the concrete plate 21 that has been suspended is loaded on the loading platform 57 a of the carry-out vehicle 57, the lower beam portion 34 is rotated with respect to the upper beam portion 33, and is returned to the original position parallel to the upper beam portion 33. At the same time, the support jig 30 is moved rearward in the continuous direction X in a state where the rotary jig 32 is raised by the lifting device 31 and returned to the original position. Thereby, it becomes possible to continue the operation of removing the main body portion 21a of the concrete plate 21 at the front end portion in the next connecting direction X.

  In the first embodiment, the above-described concrete plate cutting step and the main body part hanging step are repeated a predetermined number of times while moving the support base 30 and the concrete cutter device 35 to the rear side in the continuous direction X, When a predetermined number of concrete slabs 21 are suspended and removed from the front end side in the continuous direction X, the support frame 30 is further moved to the rear end side in the continuous direction X as shown in FIGS. Then, the both end portions 21c of the left concrete plate 21 are sequentially removed from the front end side by the both end portion removing step.

  In the both end portion removal process, for example, by the work by the worker who has entered the work floor 58a of the aerial work vehicle 58, the slip prevention guide member 36, the fixed anchor 23 and the like are removed from the both end portions 21c of the remaining concrete plate 21. For example, by sandwiching and lifting both end portions 21c of the concrete plate 21 by the tip attachment portion 59a of the crusher heavy machine 59, the both end portions 21c of the remaining concrete plate 21 can be easily removed.

  After removing both end portions 21c of the concrete plate 21 left in the both end portion removing step and removing all the planned concrete plates 21, the support frame 30 and the concrete cutter device moved to the rear side in the continuous direction X 35, etc. are dismantled and removed by work by a worker who has entered the work floor 58a of the aerial work vehicle 58 or work using a small crane 56, for example due to aging or change of ventilation system, etc. The construction for removing the ceiling slab 20 that needs to be removed is completed.

  And according to the suspension ceiling concrete plate suspension and removal mechanism 10 of the first embodiment having the above-described configuration, a large number of concrete plates arranged in a row and forming the ceiling plate 20 of the road tunnel 50. It is possible to facilitate the operation of raising and lowering 21 while supporting it in a balanced manner, and to secure a sufficient supporting force without damaging the top surface portion of the tunnel.

  That is, the tunnel ceiling concrete plate suspension / removal mechanism 10 according to the first embodiment is installed on the existing concrete plate 21 to be continuously provided, and can be moved in the continuous direction X. A lifting device 31 that is attached to the support frame 30 and can lift and suspend the concrete plate 21 to be removed, and a rotary jig 32 that is suspended from the lifting device 31 and rotatably supports the removed concrete plate 21. The support frame 30 has an arch shape, and has a pair of support main body portions 30a in which both end portions 30c are arranged at both end portions 21b of the existing concrete plate 21, and a support main body portion 30a. The connecting support beam portion 30b to which the elevating device 31 is attached is connected.

  Therefore, according to the first embodiment, the suspension is removed from the support base 30 having the support main body 30a having the arch shape, which is disposed in the space above the ceiling plate 20 of the road tunnel 50. Since the concrete plate 21 is supported, it is possible to support the concrete plate 21 to be removed from above with a sufficient balance and a stable state without damaging the top surface of the existing tunnel. By using the rotating jig 32, a large number of concrete plates 21 arranged in a row in the connecting direction X are efficiently suspended and removed easily without being brought into contact with an existing structure or the like. It will be possible.

  FIGS. 9A to 9C exemplify a suspension removal mechanism 10 ′ for a tunnel ceiling concrete plate according to a preferred second embodiment of the present invention. The tunnel ceiling concrete plate suspension / removal mechanism 10 ′ of the second embodiment is different from the tunnel of the first embodiment except that the structure of the support frame 30 ′ and the position of the lifting device 31 are different. It has the same structure as the suspension removal mechanism 10 for the ceiling concrete plate. With regard to the tunnel ceiling concrete plate suspension / removal mechanism 10 ′ of the second embodiment, components different from those of the tunnel ceiling concrete plate suspension / removal mechanism 10 of the first embodiment will be mainly described, and similarly. The same reference numerals are given to the components, and description thereof is omitted. For the components that are not particularly mentioned, the description regarding the suspension removal mechanism 10 for the tunnel ceiling concrete plate of the first embodiment is applied as appropriate.

  In the tunnel ceiling concrete plate suspension / removal mechanism 10 ′ according to the second embodiment, the support body 30a is connected and the connection support beam portion 30b ′ to which the elevating device 31 is attached is a concrete plate. 21 is further extended from the support main body 30a ′ provided at the distal end portion in the connecting direction X to the distal end side, and the lifting device 31 is an extended beam that is an extended portion of the connection support beam portion 30b ′. It is attached so as to be movable in the connecting direction X along the portion 30d ′.

  That is, in the second embodiment, as shown in FIGS. 9 (a) to 9 (c) and FIGS. 12 (a) to 12 (c), the support frame 30 ′ has an arch shape, and both end portions 30c ′ are provided. The support main body 30a ′ made of three H-sections and the like disposed at both ends 21b of the existing concrete slab 21 forming the ceiling slab 20 at intervals in the connecting direction X, and these A connection made of an I-shaped steel or the like, which is provided on the upper part of the support body 30a ′ so as to extend in the continuous direction X and connects the support body 30a ′ and to which the lifting device 31 is attached. And a support beam portion 30b ′. The connection support beam portion 30b ′ is provided so as to extend further to the front end side than the support main body portion 30a ′ at the front end portion in the connecting direction X, and the protruding portion corresponds to the lifting device 31. An overhanging beam portion 30d ′ to be attached is provided.

  In the tunnel ceiling concrete plate suspension / removal mechanism 10 ′ of the second embodiment, for example, a cradle installation step (see FIGS. 10A to 10C) described later and a concrete plate suspension step (FIG. 11). (See (a) to (c)) and a supporting member removing step (see FIGS. 12 (a) to (c)), a number of concrete plates 21 that form the ceiling plate 20 are suspended and removed. Can be lifted and removed sequentially.

  In the gantry installation process (see FIGS. 10A to 10C), a simple device such as a winch is used as in the gantry installation process by the tunnel ceiling concrete plate removing mechanism 10 of the first embodiment described above. In a state of being disassembled into members of a size and weight that can be assembled by a worker's manual work, the components of the support gantry 30 ′ and the lowering removal mechanism 10 ′ are transported to the construction site of the road tunnel 50 by the transport vehicle 55, The transported components and the like are lifted by using, for example, a small crane 56 and transported onto the existing ceiling slab 20 to be removed, and the worker is transported by work on the existing ceiling slab 20. The lifting / removing mechanism 10 including the lifting / lowering device 31 having the above-described configuration, the rotary jig 32, the support frame 30 ′, and the like is assembled using the apparatus and the equipment.

  Similarly to the first embodiment described above, a known chill tank is preferably attached as a moving wheel member 37 to both end portions 30c ′ of the plurality of arch-shaped support main body portions 30a ′, and is connected continuously. A slip guide member made of, for example, L-shaped steel is attached to both end portions 21b of the concrete plate 21 forming the existing ceiling plate 20 so as to extend along the connecting direction X of the concrete plate 21. Keep it.

  In the concrete plate suspension process, as shown in FIGS. 11A to 11C, the support frame 30 ′ is placed on the concrete plate 21 on the rear end side of the concrete plate 21 on the front end portion in the connecting direction X. The position where the bracket plate 22 is moved by the lifting / lowering device 31 after the concrete plate 21 at the tip is temporarily lifted by the lifting / lowering device 31 attached to the overhanging beam portion 30d ′ of each connection support beam portion 30b ′. After the concrete plate 21 at the front end is moved to the end, the concrete plate 21 at the front end is suspended below the bracket member 22.

  Further, in the concrete plate suspension process, for example, the support main body 30a ′ of the support frame 30 ′ provided at the front end portion in the continuous direction X is the rear end portion of the concrete plate 21 at the front end portion in the continuous direction X. When the support frame 30 ′ is moved so as to be installed on the concrete plate 21 adjacent to the side, it is preferable to fix the support frame 30 ′ at the moved position. The support frame 30 ′ is fixed by fixing the support main body 30 a ′ at the rear end portion in the connecting direction X to a displacement prevention guide member extending in the connecting direction X at both end portions 21 b of the concrete plate 21. The support main body 30 a ′ at the rear end of the connecting direction X can be directly fixed to the concrete plate 21. As a result, when the concrete plate 21 at the front end is lifted by the elevating device 31 attached to the overhanging beam portion 30d ′ of each connected support beam portion 30b ′, the rear end side of the support stand 30 is lifted and the support stand is lifted. It becomes possible to avoid effectively that 30 'becomes unstable.

  In the second embodiment, when the support frame 30 ′ is installed on the concrete plate 21 on the rear end side in the connecting direction X, the lifts attached to the overhanging beam portions 30 d ′ of the respective connection support beam portions 30 b ′ The apparatus 31 lifts the concrete plate 21 at the tip to be removed so as to lift up. In order to lift the concrete slab 21 at the front end, an anchor member (not shown) is driven into a predetermined position of the concrete slab 21. The anchor member is driven to a portion directly above the concrete slab 21 at the front end along the beam portion 30d ′. The lower end of the suspension wire 34b extended downward from the rotary jig 32 suspended from the lift device 31 moved in this manner is locked.

  After that, the fixing anchor 23 that has fixed the concrete plate 21 to the cradle portion 22b of the bracket member 22 is removed, the connecting bolts that connect the adjacent concrete plates 21 to each other are removed, and the concrete at the tip portion is further removed. After removing the slip-off prevention guide member 36 attached to the plate 21, the lifting device 31 is operated so that the concrete plate 21 at the front end can be easily moved by the lifting device 31 with the rotary jig 32 interposed. It is possible to lift upward.

  Once the concrete slab 21 at the tip is once lifted by the lifting device 31, it is lifted by moving the lifting device 31 to the tip side in the connecting direction X along the overhanging beam portion 30d ′ of the connection support beam portion 30b ′. The concrete plate 21 at the front end is moved together with the rotary jig 32 to a position where the remaining bracket member 22 at the front end side supporting the concrete plate 21 at the front end is replaced from below. As a result, the bracket member 22 that hinders the suspension is not present below the suspended concrete plate 21 at the tip, so that the concrete plate 21 at the tip is smoothly suspended downward by the lifting device 31. It becomes possible.

  In the concrete plate suspending step, the concrete plate 21 at the leading end to be suspended is moved from the lower beam part 34 of the rotary jig 32 to the upper beam part 33 in a space region below the bracket member 22 that is left behind. By rotating (refer to FIG. 11 (a)), preferably, the longitudinal direction L is smoothly rotated and moved along the continuous direction X, and is then suspended downward. As a result, inside the road tunnel 50, the vertically long loading platform 57 a is extended in the continuous direction X of the concrete plate 21, which is the axial direction of the road tunnel 50, and moved to a portion directly below the overhanging beam portion 30 d ′. The concrete plate 21 that is suspended and removed from the loading platform 57a of the unloading vehicle 57 such as a trailer can be smoothly loaded and unloaded.

  When the main body portion 21 a of the concrete plate 21 that has been suspended is loaded on the loading platform 57 a of the carry-out vehicle 57, the lower beam portion 34 is rotated with respect to the upper beam portion 33, and is returned to the original position parallel to the upper beam portion 33. At the same time, the support jig 30 ′ is moved rearward in the connecting direction X in a state where the rotary jig 32 is raised by the elevating device 31 and returned to the original position. Thereby, it becomes possible to continue the operation of removing the concrete plate 21 at the front end portion in the next connecting direction X.

  In the supporting member removing step, as shown in FIGS. 12A to 12C, after the concrete plate hanging step, the four ends supporting the both end portions 21b of the concrete plate 21 at the tip of the suspended portion are supported. Of the bracket member 22, the remaining two bracket members 22 on both sides on the front end side are removed. In the support member removing step, the left bracket member 22 can be easily removed by, for example, a work performed by a worker who has entered the work floor 58a of the aerial work vehicle 58.

  When the above-described main body part hanging step and the supporting member removing step are repeated a predetermined number of times to remove all the planned concrete plates 21 and bracket members 22, the tunnel ceiling concrete plate of the first embodiment described above is removed. Similar to the suspension removal method by the removal mechanism 10, the work by the worker who got on the work floor 58 a of the aerial work vehicle 58, such as the support platform 30 ′ moved to the rear side in the continuous direction X, By the work using the small crane 56, dismantling and removal, for example, the work of removing the ceiling slab 20 that has become necessary to be removed due to aging, change of the ventilation system, or the like is completed.

  The tunnel ceiling concrete plate suspension / removal mechanism 10 ′ according to the second embodiment having the above-described configuration also includes an arch shape disposed in a space above the ceiling plate 20 of the road tunnel 50. By supporting the concrete plate 21 to be removed by suspending it from the support frame 30 ′ having the support main body 30 a ′, it is stable with sufficient support without damaging the top surface of the existing tunnel. In this state, the concrete plate 21 to be removed can be supported in a well-balanced manner from above, and can be connected to the continuous installation direction X through the rotating jig 32 without being brought into contact with an existing structure or the like. Since a large number of concrete plates 21 to be installed can be suspended efficiently and easily removed, the first embodiment described above can be used. Same effects as removal mechanism 10 of the tunnel ceiling concrete panel can be exhibited.

  The present invention is not limited to the above-described embodiments, and various modifications can be made. For example, a concrete plate that is removed by the suspension and removal mechanism of the present invention and that is supported by supporting members at both ends and arranged in a row in a continuous direction forms a tunnel ceiling plate of a road tunnel. It does not necessarily need to be a thing, and may form another tunnel ceiling plate.

  Further, it is not always necessary that the wheel member and the spacing member are attached to both ends of the support main body, and it is not always necessary to provide the slip prevention guide members on both ends of the concrete plate.

10, 10 'Tunnel ceiling concrete plate hanging and removing mechanism 20 Ceiling plate 21 Concrete plate 21a Main body portion 21b Both ends 22 Bracket member (support member)
22a Joint base portion 22b Receiving base portion 22c Placement surface 23 Fixed anchor 30, 30 'Support base 30a, 30a' Support main body portion 30b, 30b 'Connection support beam portion 30c, 30c' Both end portions 30d 'Overhang beam portion 31 Lifting device 32 Rotating jig 33 Upper beam portion 34 Lower beam portion 34a Rotating connection portion 34b Hanging wire 37 Wheel member 50 Road tunnel 55 Transport vehicle 56 Small crane 57 Unloading vehicle 57a Loading platform 58 Height work vehicle 58a Work floor portion X Connection direction L Concrete Longitudinal direction of plate body

Claims (7)

The existing concrete plate that forms the ceiling plate of the tunnel, which is arranged in a row in the continuous direction, is supported by supporting members that extend inward from the side wall of the tunnel. A mechanism for hanging and removing the tunnel ceiling concrete slab used to suspend and remove from the concrete slab on the tip side in the direction,
A support pedestal installed on the existing concrete plate to be connected and movable in the connecting direction; a lifting device attached to the support gantry and capable of lifting and suspending the concrete plate to be removed; and A rotating jig that is provided suspended from the lifting device and rotatably supports the suspended concrete plate to be removed,
The support frame has an arch shape, and both ends are disposed at both ends of an existing concrete plate, and at least a pair of support body portions provided at intervals in the connecting direction, and these support bodies The tunnel ceiling part is provided to extend in the connecting direction at the upper part of the part, and includes a support beam part to which these support body parts are connected and to which the lifting device is attached. A mechanism to suspend and remove concrete plates.   The connection support beam portion is provided to further protrude from the support main body portion provided at the distal end portion in the connecting direction to the front end side, and the lifting device is provided at a portion where the connection support beam portion extends. The tunnel ceiling concrete slab suspending and removing mechanism according to claim 1, wherein the tunnel ceiling concrete slab is attached so as to be movable along the connecting direction.   3. The tunnel according to claim 1, wherein a pair of the connection support beam portions are provided at the same height position in the support main body portion, and the lifting device is attached to each of the connection support beam portions. Suspension and removal mechanism for ceiling concrete plate.   The rotating jig includes an upper beam portion that is suspended from the lifting device and a lower beam portion that suspends the concrete plate to be removed, and the lower beam portion is rotatably connected to the upper beam portion. The suspended ceiling concrete plate suspension / removal mechanism according to any one of claims 1 to 3, wherein the suspended concrete plate to be removed is rotated with respect to the upper beam portion.   The suspension removal mechanism of the tunnel ceiling part concrete plate of any one of Claims 1-4 by which the wheel member is each attached to the both ends of the said support main-body part.   An anti-slip guide member for preventing movement of both ends of the support main body in the connecting direction is provided in the connecting direction, while preventing both ends of the support main body from shifting to the outside at both ends of the concrete plate. 6. The suspension and removal mechanism for a tunnel ceiling concrete plate according to claim 5, wherein the suspension ceiling concrete plate is provided extending along the tunnel.   The tunnel ceiling concrete plate according to any one of claims 1 to 6, wherein a spacing member that connects both end portions of each of the support main body portions to each other is disposed and provided at a lower end portion of the support frame. Suspension removal mechanism.

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