KR101044443B1 - Slab hanging up and down apparatus for top-down method of underground construction - Google Patents

Abstract

The present invention relates to a slab elevating device for reverse construction of underground structures, and more particularly, when constructing underground structures, a plurality of slabs are constructed so that underground continuous walls and a plurality of center piles can be moved along the center piles. In the slab elevating device for the reverse construction of the underground structure to form a stack, and to move the laminated slab to the installation position, the elevating device is provided on the center pile or the underground continuous wall to stack the plurality of slabs, The slab is moved to the installation position repeatedly by a predetermined length along the longitudinal direction of the center pile or underground continuous wall by an elevating jack.

According to the present invention as described above, it is possible to move a plurality of stacked slabs to the lower side so as to be separated from each other can reduce the working time by moving the conventional slab one by one, the simple structure and the center pile and underground continuous wall It is easy to install in, and can reduce the cost as the process is reduced than the conventional can improve the work efficiency.

Underground, Structure, Construction, Reverse, Slab, Lift

Description

Slab hanging up and down apparatus for top-down method of underground construction

The present invention relates to a slab elevating device, and more particularly, when the underground structure is constructed in the reverse direction, the laminated slab can be moved downward along the height direction of the center pile or underground continuous wall by using the elevating jack. The present invention relates to a slab elevating device for reverse construction of underground structures that can lower large stacked slabs more quickly, safely and precisely than before.

Generally, the method of constructing underground structures is divided into net pouring method and reverse pouring method, and net pouring method supports the hydraulic pressure and earth pressure acting on the soil membrane while excavating the ground after constructing the soil on the ground where the underground structure is constructed. The earthen support that can be installed is to install the facilities, take out all the soil, and build the structure from the bottom floor.

And the reverse casting method is to construct the earth block and build the first floor structure, and then build the structure by excavating the ground from the top to the bottom by using the permanent structure as a brace to support the hydraulic and earth pressure acting on the earth. .

In recent years, underground structure construction has been deepened and enlarged in order to maximize land use. In particular, when the construction is carried out by the net pouring method, problems such as settlement of surrounding buildings due to the risk of earthquake collapse or displacement of surrounding ground occur. .

In addition to these problems, it is necessary to install and dismantle the temporary support facilities for the earthen fence, and thus there are various problems such as an increase in the construction cost and a longer construction period. As the structure is deepened, various other construction methods have been developed and widely applied.

This reverse casting method is a method of constructing the underground structure from the ground floor to the underground floor when constructing the underground structure, so that the construction of the underground structure and the ground structure can be carried out at the same time, and the floor of the ground floor can be used as a workshop. This is unnecessary and has the advantage of being able to work with solid formwork.

The form of mold applied in the reverse casting method is the method of placing concrete slabs and beams on the ground while the ground is stopped (concrete on grade), excaving the ground to some extent, selecting the ground, and then forming the copper bar and installing the formwork. Form on Supporting and Method of Placing Concrete by Suspending Formwork on Concrete Slabs in the Upper Floors Instead of Forming a Barrier for Formwork (Unsupported Reversal Suspending Formwork) Etc.

On the other hand, in order to build the underground structure of each floor by using the unsupported reversal suspension method, the slab and beam formwork should be installed by placing concrete on the formwork and the upper slab and beam form. For the slab and beam construction of the lower floor, the lower beam should be lowered to the height of the lower beam, and the work of lowering the formwork is repeated in the process of constructing each floor.

In general, in order to lower the beam formwork to the lower beam height as described above, a lowering device positioned above the upper slab is used.

That is, the wire connected to the lowering device is penetrated downward through the previously formed through hole in the upper slab, and then the lower end of the wire is supported on the pipe supporting the formwork, and then the lowering device is driven to release the wound wire. The die is lowered slowly.

However, in order to ensure that the formwork can be smoothly lowered in the process of lowering the formwork through wires, the formwork must be suspended by several wires instead of a single wire, and the bottom of each wire is connected to each preset position. The girder formwork must be supported and lowered in several positions.

At this time, after passing a plurality of holes in the upper slab and through each wire through each hole, each wire must be connected to each position of the lower formwork properly set, conventionally, each wire to support and lower the formwork at various locations Each lowering device was needed.

In other words, it was necessary to use several lowering devices that can unwind and wind the wires only to lower the formwork. Also, as several lowering devices must be driven at the same time, the cost of operating multiple lowering devices is increased. In each floor, the formwork, reinforcement and concrete placement must be repeated.

In order to solve this problem, as shown in FIG. 1, the slab and the formwork are moved by using a single lowering device.

However, the lowering device using the wire still has a problem that takes a lot of construction period, the structure is complicated, the cost is increased, there is a problem that the work efficiency is lowered.

In particular, as the slabs must be formed after the formwork is finished, the formwork, reinforcement, concrete placing and curing work are repeated, thus increasing the volume of material and requiring a lot of workforce. Since such work must be performed, there is a problem that the work efficiency is lowered, and the construction cost and construction period are increased.

Accordingly, the present invention has been made in order to solve the above problems, having a support guide and a frame to support and move the slab laminated to be separated from each other, and the lifting jack for moving the support guide by a predetermined length With a plurality of stacked slabs can be moved downward at the same time.

The first and second frames are provided to easily support the center pile or the underground continuous wall, and the first and second fixing parts are provided to set the moving distance of the support guide on which the laminated slab is supported. By lowering it is possible to minimize the inclination conventionally generated, it is possible to move the heavy slabs to the lower side at the same time safely, precisely and quickly.

Accordingly, it is possible to prevent the slab from being damaged and at the same time lower the number of stacked slabs safely, thereby reducing the work process and reducing time and cost, so that the reverse construction of the underground structure can improve the work efficiency. It is an object to provide a slab elevating device.

The present invention for achieving the above object, when constructing an underground structure, the basement continuous wall and a plurality of center piles are constructed, and a plurality of slabs are laminated to be moved along the center piles, and the stacked slabs are installed in positions A slab elevating device for reverse construction of an underground structure to be moved in an underground structure, wherein the elevating device is provided on the center pile or underground continuous wall to stack the plurality of slabs, and the center pile or underground continuous by elevating jacks. The slab is moved to the installation position by repeating a predetermined length along the longitudinal direction of the wall.

Preferably, the elevating device is provided with at least one or more along the longitudinal direction of the center pile, the support guide for supporting the slab hanging through the plurality of stacked slabs, the center pile or underground continuous wall And a second frame through which the support guide penetrates, and is provided on an upper side of the second frame to selectively move along the longitudinal direction of the support guide, wherein the support guide freely moves downward in contact with the second frame. A second fixing part to prevent the upper part of the second frame, the first frame penetrating the support guide, and an upper part of the first frame to selectively move along the length direction of the support guide. A first fixing part for preventing the support guide from moving downward in contact with the first frame, and the second frame; It is provided between the first frame and comprises a lifting jack for moving the laminated slab downwards by moving the support guide downward while adjusting the distance between the second frame and the first frame, the second In a state where the support guide is fixed to the center pile or the underground continuous wall by the fixing part and the second frame, the first fixing part moves a predetermined distance upward along the support guide, and then the first jack is moved by the lifting jack. The frame is moved upward to support the first fixing part, and the second fixing part moves along the support guide by the distance the first fixing part is moved, and then the first frame is moved downward by the lifting jack. As the support guide and the slab is moved downward by the interval between the second fixing part and the second frame, it is repeated.

And the lifting device is provided with at least one or more along the longitudinal direction of the center pile, the lower end is provided in the support guide for supporting the slab through the plurality of stacked slabs, the center pile or underground continuous wall, A second frame through which the support guide penetrates, and is provided on an upper side of the second frame to selectively move along the longitudinal direction of the support guide, and prevents the support guide from freely moving downward in contact with the second frame; A second fixing part provided at an upper side of the second frame and provided at an upper side of the first frame through which the support guide penetrates, and selectively movable along the longitudinal direction to the support guide; A first fixing part which prevents the support guide from moving downward in contact with a first frame, and the first frame and the first height It is provided between the government and comprises a lifting jack for moving the laminated slab to the lower side by moving the support guide downward while adjusting the distance between the first frame and the first fixing part, the second height In the state where the support guide is fixed to the center pile or the underground continuous wall by the government and the second frame, the first fixing part moves upwardly by a predetermined distance along the support guide, and then the upper end of the lifting jack is the first height. The second fixing part moves along the support guide by the distance traveled by the first fixing part, and then contracts the lifting jack so that the supporting guide and the slab are moved as the first fixing part is moved downward. It moves downward by the interval between the second fixing part and the second frame, and repeats this.

In addition, the elevating device is provided on the base continuous wall, the second frame is formed in the space portion therein, is provided in the vertical direction so as to pass through the second frame, the lower end is passed through the slab laminated slab to hang the slab A support guide to be positioned in an inner space of the second frame to be selectively moved along a longitudinal direction of the support guide, and to prevent the support guide from freely moving downward in contact with the second frame. A fixing part, a first fixing part provided on an upper side of the second frame and selectively movable along a longitudinal direction of the supporting guide, and provided between the second frame and the first fixing part, the second frame and the first fixing part It comprises a lifting jack for moving the slab downward as the support guide moves downward while adjusting the interval of the government, In a state in which the support guide is fixed to the basement continuous wall by the second fixing part and the second frame, the first fixing part moves upwardly by a predetermined distance along the supporting guide, and then the upper end of the lifting jack is fixed to the first fixing part. The second fixing part moves along the support guide by the distance traveled by the first fixing part, and then contracts the lifting jack so that the supporting guide and the slab are moved as the first fixing part is moved downward. It is moved downward by the interval between the second fixing part and the second frame and repeats this.

In addition, the elevating jack is provided with a hole through which the inside is vertically moved, and the support guide penetrates through the hole.

In addition, the support guide is formed of a circular rod, the thread is formed along the outer peripheral surface, the first fixing part and the second fixing part is formed on its inner surface to correspond to the thread of the support guide.

And further comprising a rotating device for rotating the first fixing part and the second fixing part to move along the support guide, the rotating device, a rotating motor, a rotating piece rotated by the rotating motor, the rotation of the rotating piece To the first fixing member and the second fixing member so that the first fixing member and the second fixing member move along the support guide, and the rotary motor, the rotating piece, and the connecting member in the longitudinal direction of the supporting guide. Rotating jack to move, and the rotary jack so that the position of the rotating piece and the connecting member is moved in the same position as the moving position of the first fixing and the second fixing which is moved along the support guide by the rotation of the rotary motor. It includes a control unit for controlling.

In addition, a ring plate is further provided on the first frame and the second frame that are lower than the first fixing part and the second fixing part, so that the support guides are transferred from the first fixing part and the second fixing part. Distribute the load.

And the lifting jack is operated by any one selected from hydraulic and pneumatic.

In addition, between the laminated slab and the excavated ground is further provided with a cushion portion that is expanded and contracted by the gas.

As described above, according to the slab elevating device for the reverse construction of the underground structure according to the present invention, it is possible to move a plurality of stacked slabs to the lower side so that they can be separated from each other to shorten the working time by moving the conventional slab one by one It is a very useful and effective invention that can be easily installed in the center pile and underground continuous wall because the structure is simple, and can reduce the cost as the process is reduced compared to the conventional.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

In addition, the present embodiment is not intended to limit the scope of the present invention, but is presented by way of example only, and various modifications may be made without departing from the technical gist of the present invention.

2 is a view showing a slab elevating device for the reverse construction of the underground structure according to the present invention, Figure 3 (3a ~ 3e) is a view showing the operating state of the slab elevating device for the reverse construction of the underground structure according to the present invention, Figure 4 is a view showing another embodiment of the reverse construction slab elevating apparatus of the underground structure according to the present invention, Figure 5 (5a ~ 5e) is an operation of another embodiment of the reverse construction slab elevating apparatus of the underground structure according to the present invention. Figure 6 is a view showing a state, Figure 6 is a view showing another embodiment of the slab elevating device for the reverse construction of the underground structure according to the present invention, Figure 7 (7a ~ 7e) is the reverse construction of the underground structure according to the present invention 8 is a view showing an operating state of another embodiment of the slab elevating device, Figure 8 is a rotation for operating the slab elevating device for the reverse construction of the underground structure according to the present invention 9 is a view showing the device, Figure 9 is a view showing the operating state of the rotary device for operating the slab lifting device for reverse construction of the underground structure according to the invention, Figure 10 is a reverse construction slab of the underground structure according to the present invention. FIG. 11 is a view illustrating a state in which the elevating device is further provided with a ring plate, and FIG. 11 is a view illustrating a state in which a cushion part is further provided in the slab elevating device for reverse construction of the underground structure according to the present invention.

As shown in the figure, the slab elevating device 100 for reverse construction is provided on the center pile 20 or the underground continuous wall 10 to stack a plurality of slabs 30, the center pile 20 or The slab 30 is repeatedly moved to the installation position by a predetermined length along the longitudinal direction of the underground continuous wall 10.

First, looking at the construction of the reverse underground structure, the underground continuous wall 10 and the plurality of center piles 20 are constructed on the ground, and a plurality of slabs 30 are stacked to be moved along the center pile 20. However, the slab 30 is laminated in a state where the ground excavation is not made.

And the slab 30 is formed by stacking a plurality of, is laminated so as to be separated from each other by a peeling member 40 made of any one or more selected from the release agent and the vinyl and film, by the lifting device 100 of the present invention Will move downward.

As shown in FIG. 2, the lifting device 100 includes a support guide 110, a second frame 120, a second fixing part 130, a first frame 140, a first fixing part 150, and The lifting jack 160 is configured.

The support guide 110 is provided with at least one along the longitudinal direction of the center pile 20, and the slab 30 is supported by hanging through the slab 30 having a plurality of lower ends.

The second frame 120 is provided on the center pile 20 or the underground continuous wall 10, and the support guide 110 penetrates through the second frame 120.

The second fixing part 130 is provided on the upper side of the second frame 120 to be selectively moved along the longitudinal direction of the support guide 110, the support guide 110 in contact with the second frame 120 is lower To prevent free movement.

In addition, the first frame 140 is provided on the upper side of the second frame 120, the support guide 110 is penetrated, the first fixing part 150 is provided on the upper side of the first frame 140, the support guide It is selectively movable along the longitudinal direction of the 110, it is in contact with the first frame 140 to prevent the support guide 110 is moved to the lower side.

And the lifting jack 160 is provided between the second frame 120 and the first frame 140 to adjust the distance between the second frame 120 and the first frame 140, the support guide 110 By moving downward, the stacked slabs 30 are moved downward.

Referring to the operation of the elevating device 100, as shown in Figure 3, the support guide 110 by the second fixing part 130 and the second frame 120, the center pile 20 or the underground continuous wall In the fixed position (10) (Fig. 3a), the first fixing part 150 is moved upwardly by a predetermined interval (Fig. 3b) in the longitudinal direction of the support guide 110, and then to the lifting jack 160 As a result, the first frame 140 is moved upward to support the first fixing part 150 (FIG. 3C).

As shown in FIG. 3D, the second fixing unit 130 is moved upward along the support guide 110 by the distance that the first fixing unit 150 is moved, and then is lifted by the elevating jack 160. As the first fixing part 150 and the first frame 140 are moved downward (FIG. 3e), the support guide 110 and the slab 30 are moved downward.

At this time, the support guide 110 and the slab 30 is moved downward by the interval between the second fixing part 130 and the second frame 120.

As described above, as the operations shown in FIGS. 3A to 3E are repeatedly performed, the slab 30 may be safely moved downward, and a plurality of stacked slabs 30 may be simultaneously moved.

And the slab 30 moved to the lower side is moved to each installation position, it is fixed to the center pile 20 and the underground continuous wall 10 through a separate fixing is used as the floor of each basement floor.

At this time, the support guide 110 is formed of a circular rod, the thread is formed along the outer circumferential surface, the first fixing part 150 and the second fixing part 130 is to correspond to the thread of the support guide 110 The inner surface is formed.

This thread prevents the first fixing part 150 and the second fixing part 130 from being moved in the vertical direction from the support guide 110, and the first fixing part 150 and the second fixing part 130. As the slab 30 is supported by the first frame 140 and the second frame 120, the slab 30 is prevented from being moved downward by an unexpected external force or load.

As shown in FIG. 4, the lifting device 100 ′ includes the support guide 110 ′, the second frame 120 ′, the second fixing part 130 ′, the first frame 140 ′, and the first frame 100 ′. Consists of the fixing part 150 'and the lifting jack 160', the lifting jack 160 'is provided between the first frame 140' and the first fixing part 150 '.

At least one support guide 110 ′ is provided along the longitudinal direction of the center pile 20, and supports the slab 30 by passing through the slab 30 having a plurality of lower ends.

The second frame 120 ′ is provided at the center pile 20 or the underground continuous wall 10 so that the support guide 110 ′ penetrates, and the second fixing part 130 ′ is the second frame 120 ′. It is provided on the upper side of the support guide 110 'can be selectively moved along the longitudinal direction, and the support guide 110' in contact with the second frame 120 'to prevent the movement to the lower side.

In addition, the first frame 140 ′ is provided on the upper side of the second frame 120 ′ so that the support guide 110 ′ penetrates, and the first fixing part 150 ′ is disposed on the upper side of the first frame 140 ′. It is provided to be selectively moved along the longitudinal direction of the support guide (110 ').

The first fixing part 150 'serves to prevent the support guide 110' from moving downward in contact with the first frame 140 '.

The elevating jack 160 'is provided between the first frame 140' and the first fixing part 150 'to support the guide while adjusting the gap between the first frame 140' and the first fixing part 150 '. By moving 110 'downward, the laminated slab 30 is moved downward.

As shown in FIG. 5, the lifting guide 100 ′ is operated by the second fixing part 130 ′ and the second frame 120 ′ by the support guide 110 ′. In a state of being fixed to the continuous wall 10 (FIG. 5A), the first fixing part 150 'is moved upwards by a predetermined distance (FIG. 5B) along the support guide 110', and then the lifting jack 160 ') Is inflated so as to contact the first fixing part 150' (FIG. 5C).

As shown in FIG. 5D, the second fixing part 130 ′ moves the support jack 110 ′ by the distance that the first fixing part 150 ′ is moved, and then moves the lifting jack 160 ′. The slab 30 is moved downward by moving the fixed first fixing part 150 'and the support guide 110' downward (Fig. 5e).

In this case, the support guide 110 'and the slab 30 are moved downward by the interval between the second fixing part 130' and the second frame 120 '.

As described above, as the operations illustrated in FIGS. 5A to 5E are repeatedly performed, the slab 30 may be safely moved downward, and a plurality of stacked slabs 30 may be simultaneously moved.

And the slab 30 moved to the lower side is moved to each installation position, it is fixed to the center pile 20 and the underground continuous wall 10 through a separate fixing is used as the floor of each basement floor.

At this time, the support guide 110 'is formed of a circular rod, the thread is formed along the outer circumferential surface, the first fixing part 150' and the second fixing part 130 'is the thread of the support guide 110' The inner surface is formed to correspond to.

This thread prevents the first fixing part 150 'and the second fixing part 130' from being moved up and down in the support guide 110 ', and the first fixing part 150' and the second fixing part 150 '. As the support 130 'is supported by the first frame 140' and the second frame 120 ', the support guide 110' with the slab 30 is moved downward by an unintentional external force or load. To prevent it.

As shown in FIG. 6, the lifting device 100 ″ includes a support guide 110 ″, a second frame 120 ″, a second fixing unit 130 ″, a first fixing unit 150 ″, and a lifting unit. Jack 160 ".

The second frame 120 ″ is provided on the underground continuous wall 10, and a space portion is formed inside the second fixing portion 130 ″.

The support guide 110 ″ is provided in the vertical direction to penetrate the second frame 120 ″, and the lower end penetrates the plurality of slabs 30 to support the slab 30.

In addition, the second fixing part 130 ″ is positioned in the inner space of the second frame 120 ″ to be selectively moved along the longitudinal direction of the support guide 110 ″, and the second frame 120 ″ is provided. The support guide 110 "is prevented from moving downward in contact with the contact.

The first fixing part 150 "is provided on the upper side of the second frame 120" and can be selectively moved along the longitudinal direction to the support guide 110 ", and the support guide 110 is in contact with the lifting jack 160". ") Is prevented from moving downward.

The lifting jack 160 " is provided between the second frame 120 " and the first fixing part 150 " to adjust the distance between the second frame 120 " and the first fixing part 150 " Moving the slab 30 downward causes the slab 30 to move downward.

As shown in FIG. 7, the elevating device 100 ″ is operated by the second fixing part 130 ″ and the second frame 120 ″ where the support guide 110 ″ is connected to the underground continuous wall 10. In the fixed position (FIG. 7A), the first fixing part 150 "is moved upwards by a predetermined distance (FIG. 7B) along the support guide 110", and then the upper end of the elevating jack 160 "is removed. Expand (FIG. 7C) so as to contact the fixing part 150 ".

As shown in FIG. 7D, the second fixing part 130 ″ moves along the support guide 110 ″ by the distance that the first fixing part 150 ″ is moved, and then the lifting jack 160 ″. The slab 30 is moved downward as the first fixing part 150 " and the support guide 110 " are moved downward (FIG. 7E).

At this time, the support guide 110 ″ and the slab 30 are moved downward by the interval between the lower end of the inner space of the second frame 120 ′ and the second fixing part 130 ′.

As described above, as the operations of FIGS. 7A to 7E are repeatedly performed, the slab 30 may be safely moved downward, and a plurality of stacked slabs 30 may be simultaneously moved.

And the slab 30 moved to the lower side is moved to each installation position, it is fixed to the underground continuous wall 10 through a separate fixing is to be used as the floor of each basement floor.

At this time, the support guide 110 "is formed of a circular rod, the thread is formed along the outer circumferential surface, the first fixing part 150" and the second fixing part 130 "is the thread of the support guide 110" The inner surface is formed to correspond to.

This thread prevents the first fixing part 150 "and the second fixing part 130" from being moved up and down in the support guide 110 ", and the first fixing part 150" and the second fixing part 150 ". The government 130 "is supported by the second frame 120" and the lifting jack 160 "so that the slab 30 is moved downward by unintentional external force or load by the medallion support guide 110". Will be prevented.

And the lifting jacks 160, 160 ', 160 "of each embodiment is operated by any one selected from hydraulic and pneumatic, in the present invention, it is preferable to operate hydraulically.

In addition, the lifting jacks 160 ′ and 160 ″ used in FIGS. 4 to 7 may be vertically penetrated in the vertical direction, and the support guides 110 ′ and 110 ″ may penetrate through the holes.

Meanwhile, as shown in FIGS. 8 to 9, the first fixing parts 150, 150 ′, 150 ″ and the second fixing part 130 are operated to automatically operate the lifting devices 100, 100 ′, 100 ″. , 130 ', 130 "may be further provided with a rotating device 200 for moving along the support guides (110, 110', 110").

The rotating device 200 is composed of a rotating motor 210 and the rotating piece 220, the connecting member 230, the rotating jack 240 and the control unit 250, the rotating piece 220 is a rotating motor 210 Is rotated by

The connecting member 230 connects the rotating piece 220 and the first fixing part 150, 150 ′ and 150 ″ or the rotating piece 220 and the second fixing part 130, 130 ′ and 130 ″ to rotate the motor. Along the support guides 110, 110 ′, 110 ″, the first fixing 150, 150 ′, 150 ″ or second fixing 130, 130 ′, 130 ″ is transmitted as the rotation of 210 is transmitted. Will be moved.

At this time, the rotary jack 240 is to move the rotary motor 210, the rotary piece 220 and the connecting member 230 in the longitudinal direction of the support guides (110, 110 ', 110 "), the support guide 110 , 110 ', 110 ") to be positioned in the same position as the first fixing parts 150, 150', 150" or the second fixing parts 130, 130 ', 130 ".

The position movement is performed by the controller 250, and the controller 250 controls the lifting jack 240 to control the first fixing parts 150, 150 ′, 150 ″ or the second fixing parts 130, 130 ′, 130 ") to move the rotating motor 210, the rotating piece 220 and the connecting member 230 in the same position.

The operation of the rotating device 200 will be described with reference to the lifting device 100 of FIGS. 2 to 3, as shown in FIG. 9, the rotating piece 220 is rotated by the rotating motor 210 and rotated. As the connecting member 230 is rotated by the piece 220, the first fixing part 150 or the second fixing part 130 is moved upward along the support guide 110.

At this time, the controller 250 measures the position of the first fixing part 150 or the second fixing part 130 to move the rotary motor 210, the rotating piece 220 and the connecting member 230 in the same manner. The rotary jack 240 is to be controlled.

When the first fixing part 150 or the second fixing part 130 is moved to a certain height, the operation of the rotating motor 210 is stopped, and the first frame is lifted by the lifting jack 160 of the boarding device 100. 140 comes into contact with the first fixing part 150.

After the second fixing part 130 is moved upward along the supporting guide 110, the first frame 140, the first fixing part 150, and the supporting guide 110 are moved by the lifting jack 160. When moving downward, the control unit 250 controls the rotary jack 240 to move the rotary motor 210 and the rotary piece 220 and the connecting member 230 in the same downward direction.

At this time, the rotation device 200 is also provided in the movement of the second fixing unit 130 and operates in the same manner as moving the first fixing unit 150, and the first fixing unit 150 and the second fixing unit 130 Rotating device 200 to operate is preferably controlled by one control unit 250.

By repeating such an operation, the elevating device 100 is automatically controlled, and the laminated slab 30 can be easily moved downward.

As shown in FIG. 10, the ring plate 300 is further provided on the first frame 140 and the second frame 120 which are lower sides of the first fixing part 150 and the second fixing part 130. In addition, the ring plate 300 has a wider upper / lower end surface than the first fixing part 150 and the second fixing part 130.

In other words, the first fixing part 150 and the second fixing part 130 form a larger contact area than the area directly contacting the first frame 140 and the second frame 120 to form the first fixing part 150. And it is preferable to distribute the load of the support guide 110 and the laminated slab 30 is transmitted from the second fixing portion 130.

On the other hand, the ring plate 300 may be provided in all parts in contact with the first fixing part 150 and the second fixing part 130.

In addition, as shown in Figure 11, between the lower slab 30 of the stacked slabs and the excavated ground is further provided with a cushion unit 400 that is expanded and contracted by the gas lift device (100, 100 ', 100 ") and the lowering speed of the slab 30 can be adjusted, and the slab 30 can be prevented from tilting to one side.

The cushion unit 400 is preferably expanded and contracted using air, and may be installed in the entire lower side of the slab 30 or may be provided in a part where load is concentrated.

1 is a view showing a descending device for reverse casting a conventional formwork or slab,

2 is a view showing a slab elevating device for the reverse construction of the underground structure according to the present invention,

3 (3a to 3e) is a view showing the operating state of the slab elevating device for the reverse construction of the underground structure according to the present invention,

4 is a view showing another embodiment of the slab elevating device for the reverse construction of the underground structure according to the present invention,

5 (5a to 5e) is a view showing the operating state of another embodiment of the slab elevating device for the reverse construction of the underground structure according to the present invention,

6 is a view showing another embodiment of the slab elevating device for the reverse construction of the underground structure according to the present invention,

7 (7a to 7e) is a view showing the operating state of another embodiment of the slab elevating device for the reverse construction of the underground structure according to the present invention,

8 is a view showing a rotating device for operating the slab elevating device for the reverse construction of the underground structure according to the present invention,

9 is a view showing an operating state of the rotary device for operating the slab elevating device for the reverse construction of the underground structure according to the present invention,

10 is a view showing a state in which the ring plate is further provided in the slab elevating device for the reverse construction of the underground structure according to the present invention,

11 is a view showing a state in which the cushion unit is further provided in the slab elevating device for the reverse construction of the underground structure according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10: continuous wall 20: center pile

30: slab 100, 100 ', 100 ": lifting device

110, 110 '110 ": Supporting guide 120, 120', 120": 2nd frame

130, 130 ', 130 ": 2nd fixed part 140, 140': 1st frame

150, 150 ', 150 ": 1st Government 160, 160', 160": Lift Jack

200: rotating device 210: rotating motor

220: rotating piece 230: connecting member

240: rotary jack 250: control unit

300: ring plate 400: cushion portion

Claims (10)

When constructing an underground structure, the underground continuous wall and a plurality of center piles are constructed, and a plurality of slabs are stacked to be moved along the center pile, and the reverse construction of the underground structures for moving the stacked slabs to the installation position is performed. In slab hoisting device, The lifting device, It is provided on the center pile or underground continuous wall to stack the plurality of slabs, and by repeating a predetermined length along the longitudinal direction of the center pile or underground continuous wall by lifting jacks to move the slab to the installation position. Slab hoisting device for reverse construction of the underground structure characterized in that. According to claim 1, The lifting device, A support guide provided with at least one along the longitudinal direction of the center pile, the lower end penetrating the plurality of stacked slabs to support the slab; A second frame provided in the center pile or the base continuous wall and through which the support guide passes; A second fixing part provided on an upper side of the second frame to selectively move along the longitudinal direction of the support guide, and preventing the support guide from freely moving downward in contact with the second frame; A first frame provided on an upper side of the second frame and through which the support guide penetrates; A first fixing part provided on an upper side of the first frame to selectively move along the longitudinal direction of the support guide and preventing the support guide from moving downward in contact with the first frame; And A lifting jack provided between the second frame and the first frame to move the laminated slab downward as the support guide is moved downward while adjusting the distance between the second frame and the first frame. under, In a state where the support guide is fixed to the center pile or the underground continuous wall by the second fixing part and the second frame, the first fixing part is moved upwardly by a predetermined distance along the supporting guide, and then by the lifting jack. The first frame is moved upward to support the first fixing part, and the second fixing part is moved along the support guide by the distance that the first fixing part is moved, and then the first frame is moved by the lifting jack. As the support guide and the slab is moved to the lower side by the interval between the second fixing part and the second frame as moved downward, the slab elevating device for the reverse construction of the underground structure, characterized in that to repeat this. According to claim 1, The lifting device, A support guide provided with at least one along the longitudinal direction of the center pile, the lower end penetrating the plurality of stacked slabs to support the slab; A second frame provided in the center pile or the base continuous wall and through which the support guide passes; A second fixing part provided on an upper side of the second frame to selectively move along the longitudinal direction of the support guide, and preventing the support guide from freely moving downward in contact with the second frame; A first frame provided on an upper side of the second frame and through which the support guide penetrates; A first fixing part provided on an upper side of the first frame to selectively move along the longitudinal direction of the support guide and preventing the support guide from moving downward in contact with the first frame; And A lifting jack provided between the first frame and the first fixing part to move the laminated slab downward as the support guide is moved downward while adjusting the distance between the first frame and the first fixing part. Done by In a state where the support guide is fixed to the center pile or the underground continuous wall by the second fixing part and the second frame, the first fixing part moves upwardly along the supporting guide at a predetermined interval, and then the upper end of the lifting jack. The second fixing unit is expanded to reach the first fixing unit, and the second fixing unit moves along the support guide by the distance traveled by the first fixing unit, and then contracts the lifting jack to support the supporting unit as the first fixing unit is moved downward. Slab hoisting device for reverse construction of the underground structure, characterized in that the guide and the slab is moved downward by the interval between the second fixing part and the second frame, and repeating this. According to claim 1, The lifting device, A second frame provided on the base continuous wall and having a space formed therein; A support guide provided in the vertical direction to penetrate the second frame and supporting the slab by penetrating the slab having a lower end stacked therein; A second fixing part positioned in an inner space of the second frame to be selectively moved along a longitudinal direction of the support guide, the second fixing part being in contact with the second frame to prevent the support guide from freely moving downward; A first fixing part provided on an upper side of the second frame and selectively movable along the longitudinal direction of the support guide; And And a lifting jack provided between the second frame and the first fixing part to move the slab downward as the support guide is moved downward while adjusting the distance between the second frame and the first fixing part. In a state in which the support guide is fixed to the basement continuous wall by the second fixing part and the second frame, the first fixing part moves upwardly by a predetermined distance along the supporting guide, and then the upper end of the lifting jack is first The second fixing part moves along the support guide by the distance that the first fixing part is moved, and then contracts the lifting jack so that the first fixing part is moved downward so that the supporting guide and the slab are moved. Is moved downwards by the interval between the second fixing part and the second frame, the slab elevating device for the reverse construction of the underground structure, characterized in that for repeating this. The method according to claim 3 or 4, The elevating jack is a slab elevating device for the reverse construction of the underground structure, characterized in that the inside is through the vertical hole, the through hole is provided so that the support guide is moved through. The method according to claim 2 or 3 or 4, The support guide is formed of a circular rod, the thread is formed along the outer circumferential surface, the first fixing part and the second fixing part of the underground structure, characterized in that the inner surface is formed so as to correspond to the thread of the support guide Construction slab elevating device. The method of claim 6, The first fixing unit and the second fixing unit is further provided with a rotating device for moving along the support guide, The rotating device, Rotary motor; A rotating piece rotated by the rotating motor; A connection member for transmitting the rotation of the rotating piece to the first fixing part and the second fixing part so that the first fixing part and the second fixing part move along the support guide; A rotary jack for moving the rotary motor, the rotary piece, and the connecting member in the longitudinal direction of the support guide; And And a control unit for controlling the rotary jack to move the position of the rotating piece and the connection member in the same manner as the moving position of the first fixing part and the second fixing part which are moved along the support guide by the rotation of the rotating motor. Slab hoisting device for reverse construction of the underground structure. The method of claim 7, wherein Ring plates are further provided on the first frame and the second frame below the first fixing part and the second fixing part to support the load of the slab laminated with the support guides transmitted from the first fixing part and the second fixing part. Slab hoisting device for reverse construction of the underground structure characterized in that the dispersion. The method according to claim 2, 3 and 4, The lifting jack is a slab elevating device for the reverse construction of the underground structure, characterized in that operated by any one selected from hydraulic and pneumatic. The method of claim 1, The slab elevating device for the reverse construction of the underground structure, characterized in that the cushion is further expanded and contracted by the gas between the laminated slab and the excavated ground.

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