KR101149567B1 - Concrete form for elevator shaft - Google Patents

Abstract

PURPOSE: A form device for an elevator hoistway is provided to easily separate the form device from concrete by moving a support shaft from a support position to a separation position. CONSTITUTION: A form device(1) for an elevator hoistway comprises four support panels(100), four support shafts(200), shaft position control units, and top position control units(400). The support panels are arranged in a square shape to form an elevator hoistway. The support shafts are arranged on the corners of the support panels and are moved from support positions to separation positions. The shaft position control units and the top position control units are arranged on the bottoms and tops of the support shafts and move the support shafts from the support position to the separation position.

Description

Formwork device for elevator hoistway {CONCRETE FORM FOR ELEVATOR SHAFT}

The present invention relates to a formwork device for an elevator hoist, and more particularly, to a formwork device for an elevator hoist in which the structure is easily removable.

In general, when building a high-rise apartment or high-rise building to be installed, an elevator is installed so that the elevator can operate the elevator, and the elevator is usually provided in a rectangular shape, the elevator is usually provided in the vertical direction according to the number of floors of the building. It is constructed in communication.

The elevator hoistway is sequentially connected from the lower floor to the upper floor in order to construct the entire skeleton of the building, and formwork is usually used for pouring concrete.

Formwork for constructing a conventional elevator hoist consists of a rectangular panel manufactured by combining a plurality of panels with each other. Conventional elevator hoisting method is to assemble the concrete panel after assembling the rectangular panel in the rectangular shape. When the curing of the concrete is completed, the panel is separated from the concrete and moved to the upper area to construct an elevator hoistway of the next height.

However, in order to separate a plurality of panels from the concrete after curing, there are many contact surfaces, which requires a lot of manpower and time.

An object of the present invention is to solve the above problems, to provide a formwork apparatus for an elevator hoisting structure improved to be more easily separated from concrete.

One aspect of the present invention for achieving the above technical problem relates to a formwork device used for the concrete construction of the elevator hoisting. Formwork apparatus of the present invention, a plurality of support panels coupled to each other to form a square; A plurality of support shafts detachably disposed at the edge regions of the plurality of support panels; It is connected to the lower region of the support shaft between the support position is inserted between the support panel to support the curing of the concrete and the separation position for moving the interior of the support panel to separate the support panel from the cured concrete And including a shaft position adjusting portion for adjusting the position to move, the shaft position adjusting portion, the shaft connecting rod is fixedly coupled to the support shaft; A moving box coupled to the other end of a pair of shaft connecting rods connected to a pair of adjacent support shafts, and having a female thread formed therein; A control rod penetrating inside the moving box and having a male screw formed on a plate surface; The moving box is coupled to the adjusting rod and rotates the adjusting rod so that the moving box moves linearly along the adjusting rod by screwing the male screw and the female screw so that the supporting shaft is moved between the supporting position and the separating position. Contains a handle.

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According to one embodiment, it further comprises an upper position adjusting portion coupled to the upper region of the support shaft for moving the support shaft to the support position and the separation position.

According to one embodiment, the upper position adjusting portion, and the first upper control rod coupled to both ends to a pair of support shafts arranged in a diagonal direction; A second upper adjusting rod disposed in a diagonal direction with the first upper adjusting rod and having both ends coupled to the remaining pair of supporting shafts; And a connection box coupled to the intersection of the first upper adjustment rod and the second upper adjustment rod, wherein the first upper adjustment rod and the second upper adjustment rod are axially adjusted by screwing to support the support shaft. Position and the separation position can be moved.

The formwork device for an elevator hoist according to the present invention moves the support shaft from the support position to the separation position, not the support panel, so that it can be separated from the concrete by introducing a relatively short time and attraction force as compared with moving the conventional support panel.

In addition, since the support shaft can be moved to the separation position by a simple operation of rotating the adjusting handle, the entire work process can be simplified.

1 is a perspective view showing the configuration of a formwork apparatus for an elevator hoist of the present invention,
Figure 2 is a perspective view showing the configuration of the shaft position adjusting portion of the formwork apparatus for elevator hoist of the present invention,
Figure 3 is a plan view showing a planar configuration of the formwork device for elevator hoist of the present invention,
Figure 4 is an enlarged perspective view showing the connection structure of the support shaft and the shaft connecting rod of the formwork device for an elevator hoist of the present invention,
5A and 5B are plan views showing a structure in which the support shaft of the formwork apparatus for elevator hoisting apparatus of the present invention is moved from a supporting position to a separating position;
Figure 6a and Figure 6b is a cross-sectional view showing a state in the support position and the separation position using the axial position control portion of the formwork apparatus for elevator hoist of the present invention,
Figure 7 is a perspective view showing the configuration of the upper position adjusting portion of the formwork apparatus for elevator hoist of the present invention,
8 is a perspective view showing the configuration of the first control rod of the upper position adjusting portion of the formwork device for elevator hoist of the present invention,
Figure 9 is a perspective view showing the configuration of the second control rod of the upper position adjusting portion of the formwork device for elevator hoist of the present invention,
10 is a cross-sectional view showing a state in the support position and the separation position using the upper position adjusting portion of the formwork apparatus for an elevator hoistway of the present invention.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiment of the present invention may be modified in various forms, the scope of the invention should not be construed as limited to the embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings and the like may be exaggerated to emphasize a more clear description. It should be noted that the same members in each drawing are sometimes shown with the same reference numerals. Detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention are omitted.

Figure 1 is a perspective view showing the configuration of the elevator hoisting apparatus of the present invention, Figure 2 is a perspective view showing the configuration of the shaft position adjusting portion, Figure 3 shows a planar configuration of the elevator hoisting apparatus for the present invention. Top view.

As shown, the formwork apparatus 1 for an elevator hoist according to the present invention includes four support panels 100 arranged in a quadrangular shape forming an elevator hoist, and a support position and a corner of the support panel 100. Four support shafts 200 to move between the separation position, and the shaft position adjusting unit 300 is disposed in the lower region of the four support shafts 200 to move the support shaft 200 from the support position to the separation position and It is disposed in the upper region of the four support shaft 200 includes an upper position adjusting unit 400 for moving the support shaft 200 from the support position to the separation position.

The support panel 100 forms the inner wall surface of the elevator hoisting path during concrete pouring. The support panel 100 is disposed in a state spaced apart from the external formwork 600 to form an outer wall surface of the elevator hoisting, and the concrete is introduced into the space spaced with the external formwork 600 to form the elevator hoisting. The support panel 100 is separated from the cured concrete A in conjunction with the support shaft 200 when the support shaft 200 is moved from the support position to the separation position.

The support panel 100 includes a panel body 110 having a predetermined area, a vertical reinforcing bar 120 and a horizontal reinforcing bar 130 supporting the panel body 110 to be disposed in a vertical state, and a shaft connecting rod 310. Includes a travel limiting plate (FIGS. 4 and 140) for limiting the maximum travel distance.

The support panel 100 is provided with four to be assembled to each other to form a square. Four support panels 100 are arranged perpendicular to each other to form a quadrangular shape, and a support shaft 200 is disposed in an edge region with neighboring support panels 100.

The panel body 110 is provided to have an area corresponding to the area of the inner wall surface of the elevator hoistway. Support plate 112 for supporting the support shaft 200 is inclined in both end regions of the panel body 110, the inner side of the support plate 112 forms a free space for the support plate 112 can be elastically deformed. Spaced apart groove 111 is provided.

A plurality of concrete inlets 115 are formed through the plate surface of the panel body 110. Concrete inlet 115 is formed in the upper region of the panel body 110, the concrete is to be poured up to the height of the concrete inlet 115.

On the other hand, at least one of the four panel body 110 is formed through the entrance 113 through which the operator can enter.

The vertical reinforcement bar 120 and the horizontal reinforcement bar 130 are coupled to the rear surface of the panel body 110 to support the panel body 110 to maintain a vertical state during the curing time of the concrete. The vertical reinforcing bar 120 and the horizontal reinforcing bar 130 are provided in plural at regular intervals.

As shown in FIG. 4, the movement limiting plate 140 protrudes in a direction perpendicular to both sides of the panel body 110 to limit the maximum movement distance of the support shaft 200. The movement limiting plate 140 is in contact with the panel support part 210 when the shaft connecting rod 310 is moved inward and limits the maximum moving distance of the support shaft 200.

The support shaft 200 is provided at four corner regions of the support panel 100 to move between the support position (Fig. 5a position) and the separation position (Fig. 5b) by the shaft position adjusting unit 300, and from the concrete (A). The support panel 100 to be easily separated.

The support position is inserted between the edges of the two support panels 100 in which the support shafts 200 are adjacent to each other so that the support shafts 200 are poured together with the support panels 100 while the concretes A are being poured. It is the position that keeps close contact with. The separation position is a position in which the support shaft 200 is moved inwards between the edges of the two support panels 100 so that the support shaft 200 is separated from the inner wall surface of the cured concrete A.

The support shaft 200 is provided to have a triangular shape as a whole so that the support shaft 200 can be easily inserted and separated between the edges of the support panel 100. The support shaft 200 includes a panel support portion 210 in contact with the support plate 112 of the panel body 110, and an insertion portion 220 protruding from a vertex region of the panel support portion 210. The panel support part 210 and the insertion part 220 are opened, and the axial connecting rod 310 is connected between the open spaces.

The support shaft 200 maintains the vertical position as shown in FIG. 6A at the support position, and moves to the separation position in the inward direction by the axial position adjusting unit 300 at the separation position, as shown in FIG. 6B. Keep inclined.

As the support shaft 200 is inclined inward, the insertion portion 220 of the support shaft 200 is moved into the support panel 100 to be separated from the inner wall surface of the concrete (A).

Here, since the concrete A is poured only up to the height of the concrete inlet 115 of the support panel 100, even if the entire area of the support shaft 200 is not separated from the concrete A but only the lower area is inclinedly separated, the tower crane ( Support panel 100 and the support shaft 200 can be sufficiently separated by the lifting force of the (not shown).

On the other hand, the support shaft 200 is provided with a coupling ring 230 for interconnecting the panel support portion 210 and the support plate 112. Coupling ring 230 is coupled to the panel support portion 210 and the support plate 112, as shown in Figure 4 when the support shaft 200 is moved to the separation position when the support panel 100 is also interlocked in the inward direction Allow a certain distance to move. As a result, when the support shaft 200 is moved to the separation position, the support panel 100 also maintains a state spaced apart from the concrete (A) to some extent.

  The shaft position adjusting unit 300 allows the support shaft 200 to move between the support position and the separation position. As a result, the support shaft 200 and the support panel 100 in which the concrete is placed are separated from the inner wall surface of the concrete A.

The shaft position adjusting unit 300 includes a shaft connecting rod 310 connected to the support shaft 200, a pair of moving boxes 320 for coupling the adjacent shaft connecting rods 310, and a moving box 320. Control rod 330 to linearly move, the adjustment handle 340 to rotate the adjustment rod 330, and the support frame 350 for supporting the axial position adjusting unit 300 with respect to the bottom surface 500 .

The shaft connecting rod 310 transmits the linear movement of the moving box 320 to the support shaft 200. The shaft connecting rod 310 has one end fixed to the support shaft 200 and the other end fixed to the moving box 320. The shaft connecting rod 310 includes a connecting rod body 311 having a predetermined length and a shaft coupling bar 313 provided at one end of the connecting rod body 311 and fixed to the support shaft 200.

 Connecting rod body 311 is arranged in a diagonal direction with respect to the square on the support panel 100 as shown in Figure 3 is connected to the moving box (320). The other end of the connecting rod body 311 is coupled by the moving box 320 and the hinge shaft 323 is rotated by the linear movement of the moving box 320.

The shaft coupling bar 313 is provided in a shape corresponding to the internal shape of the support shaft 200 and is fixed inside the support shaft 200. The shaft coupling bar 313 is integrally moved together with the moving box 320 when the connecting rod body 311 is linearly moved with the moving box 320 so that the support shaft 200 is moved to the separation position.

The moving box 320 couples a pair of neighboring shaft connecting rods 310 together so that the pair of shaft connecting rods 310 and 310a are simultaneously moved from the supporting position to the separating position. The moving box 320 includes a box body 321 coupled to the adjusting rod 330, and a hinge shaft 323 rotatably coupling the box body 321 and the pair of shaft connecting rods 310 and 310a to each other. do.

The inner surface of the box body 321 is provided with a female screw (not shown) formed to correspond to the male screw 331 of the adjustment rod 330. Accordingly, the box body 321 is a female screw (not shown) is moved along the male screw 331 when the adjusting rod 330 is rotated to move linearly along the axial direction of the adjusting rod 330.

The adjusting rod 330 is rotatably provided on the support frame 350. The adjusting rod 330 is coupled to the support frame 350 through the moving box 320. Adjusting rod 330 is a male screw 331 is formed a predetermined length on the plate surface.

The adjusting handle 340 is coupled to the center region of the adjusting rod 330 to adjust the rotation of the adjusting rod 330. The operator rotates the adjusting handle 340 to move the moving box 320 inward or outward in the axial direction along the adjusting rod 330 to move the support shaft 200 to the support position or separation position.

An elevator hoisting process using the formwork apparatus 1 for elevator hoists according to the present invention having such a configuration will be described with reference to FIGS. 1 to 6B.

First, the formwork device 1 for the elevator hoisting path is installed on the lowest floor of the building to be installed. Install the external formwork 600, the support panel 100 and the support shaft 200 to the vertical position with respect to the outer formwork 600 and the inner surface at a predetermined distance to the vertical position to the support position and square Assemble Fix the shape using the horizontal reinforcement bar 130 and the vertical reinforcement bar (120).

Then, the wire (not shown) of the tower crane (not shown) is coupled to the crane coupling hole 424a (see FIG. 9) in the upper region of the support shaft 200.

After the worker moves to the inside of the support panel 100, the concrete is injected into the concrete inlet 115. The injected concrete fills the space between the external formwork 600 and the support panel 100. When the concrete is filled up to the height of the concrete inlet 115, the concrete is stopped and the concrete is cured.

When curing of the concrete is completed and the surface of the concrete is hardened, the worker rotates the adjusting handle 340. The moving box 320 coupled to the axis of the adjusting rod 330 by the rotation of the adjustment handle 340 is linearly moved inward along the axial direction.

The shaft connecting rods 310 and 310a disposed adjacent to each other according to the linear movement of the moving box 320 are pressed inward, and the shaft coupling bar 313 and the fixed support shaft are fixed according to the pressing of the shaft connecting rods 310 and 310a. 200 is separated from the concrete A as shown in FIG. 6B and moved to the separating position.

At this time, since the position of the upper region of the support shaft 200 is fixed and only the lower region moves inwardly, the position of the upper region of the support shaft 200 is moved to the separated position in an inclined shape as a whole. When the support shaft 200 is moved to the separation position, as shown in Figure 4, the support panel 100 is also connected by the support shaft 200 and the coupling ring 230, so the concrete (A ).

When the support panel 100 and the support shaft 200 are moved to the separated position, the tower crane (not shown) lifts the wire (not shown), and the support panel 100 and the support shaft 200 are moved upwards in the next placing position. Will be moved to.

On the other hand, the formwork device 1 for an elevator hoist according to the present invention further includes an upper position adjusting part 400. In the elevator hoisting process of the above-mentioned formwork device 1, only the lower region of the support shaft 200 is moved to the separation position, and the separation is performed in an inclined state as a whole. In this case, when the upper region of the support shaft 200 and the support panel 100 that are not moved to the separation position in some cases maintains contact with the concrete A despite the lifting force of the tower crane (not shown) May be generated.

The upper position adjusting unit 400 serves to move the upper region of the support shaft 200 and the support panel 100 to the separation position in this case.

The upper position adjusting unit 400 includes a first upper adjusting rod 410, a second upper adjusting rod 420 and a connection box 430 formed to cross each other in a diagonal direction as shown in FIG. Both ends of the first upper adjustment rod 410 are coupled to a pair of support shafts 200 disposed in diagonal directions with each other. The second upper adjustment rod 420 is disposed in a diagonal direction with respect to the first upper adjustment rod 410.

As shown in FIG. 8, the first upper adjustment rod 410 has a first upper adjustment rod main body 411 having a female screw (not shown) therein, and one end thereof is connected to the support shaft 200, and the other end thereof has a first upper adjustment rod 410. One upper adjustment rod body 411 is inserted into the inside and includes a male screw shaft 415 formed with a male screw on the plate surface. The first upper control rod body 411 is disposed through the connection box 430. An insertion hole 413 into which the operating rod 417 is inserted is formed on the plate surface of the first upper adjustment rod body 411.

When the operator rotates the operating rod 417 while the operating rod 417 is inserted into the insertion hole 413, the male screw shaft 415 linearly moves into the first upper adjustment rod body 411 to move the first rod. The overall length of the upper adjustment rod 410 is adjusted. Accordingly, the upper region of the support shaft 200 can also be moved to the separation position.

The second upper control rod 420 is coupled to the first upper control rod main body 411 through the connection box 430 as shown in Figure 9 and the second upper control rod formed with a female thread (not shown) therein The main body 421, the rotation shaft 423 connected to the support shaft 200, the shaft coupling bar 424 provided at the end region of the rotation shaft 423 and connected to the support shaft 200, and the rotation shaft 423. A male thread 427 formed at the other end of the cross and a cross-shaped insertion rib 425 provided on the outer side of the region where the male thread 427 is formed and into which the operating rod 417 is inserted.

When the operator rotates the second upper adjustment rod 420 by coupling the operation rod 417 to the insertion rib 425, the male thread 427 of the rotation shaft 423 is inserted or protruded along the female thread (not shown). And moved. Accordingly, the upper region of the support shaft 200 can also be moved to the separation position.

10 is an exemplary view showing a process of moving the position of the support shaft 200 by the upper position adjusting unit 400.

As shown, not only the lower region of the support shaft 200 is moved to the separated position by the shaft position adjusting unit 300, but the upper region of the support shaft 200 is also separated by the upper position adjusting unit 400. Is moved to. Accordingly, the support shaft 200 and the support panel 100 may move horizontally from the concrete (A) to facilitate separation.

As described above, since the formwork apparatus for elevator hoisting according to the present invention moves a support shaft from a support position to a separate position, not a support panel, a relatively small amount of time and manpower are input compared to when moving a conventional support panel from concrete. Can be separated.

In addition, the support shaft can be moved to the separation position by a simple operation of rotating the adjusting handle, thereby simplifying the whole working process.

Embodiment of the formwork apparatus for an elevator hoist of the present invention described above is merely exemplary, and those skilled in the art to which the present invention pertains that various modifications and equivalent other embodiments are possible. You can see well. Therefore, it will be understood that the present invention is not limited to the forms mentioned in the above detailed description. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

1: Forming apparatus 100: Support panel
110: panel body 111: spaced groove
112: support plate 113: doorway
115: concrete inlet 120: longitudinal reinforcement bar
130: horizontal reinforcement bar 140: limited movement
200: support shaft 210: panel support
220: insertion portion 230: coupling ring
300: shaft position adjusting unit 310: shaft connecting rod
311: connecting rod body 313: shaft coupling bar
320: moving box 321: box body
323: hinge axis 330: adjusting rod
331: external thread 340: adjustment handle
350: support frame 400: upper position control
410: first upper control rod 411: first upper control rod body
413: insertion hole 415: male threaded shaft
417: operating rod 420: second upper control rod
421: second upper control rod main body 423: rotation axis
424: shaft coupling bar 424a: crane coupling hole
425: insertion rib 427: male thread
430: connection box 500: bottom
600: external formwork

Claims (4)

In the formwork device used for the concrete construction of the elevator hoisting,
A plurality of support panels coupled to each other to form a quadrangular shape;
A plurality of support shafts detachably disposed at the edge regions of the plurality of support panels;
It is connected to the lower region of the support shaft between the support position is inserted between the support panel to support the curing of the concrete and the separation position for moving the interior of the support panel to separate the support panel from the cured concrete Including an axis position adjusting unit for adjusting the position to move,
The shaft position adjusting unit,
A shaft connecting rod having one end fixedly coupled to the support shaft;
A moving box coupled to the other end of a pair of shaft connecting rods connected to a pair of adjacent support shafts, and having a female thread formed therein;
A control rod penetrating inside the moving box and having a male screw formed on a plate surface;
The moving box is coupled to the adjusting rod and rotates the adjusting rod so that the moving box moves linearly along the adjusting rod by screwing the male screw and the female screw so that the supporting shaft is moved between the supporting position and the separating position. Formwork apparatus comprising a handle.
delete The method of claim 1,
And an upper position adjusting unit coupled to the upper region of the support shaft to move the support shaft to the support position and the separation position.
The method of claim 3,
The upper position adjusting unit,
A first upper control rod having both ends coupled to a pair of support shafts disposed in a diagonal direction;
A second upper adjusting rod disposed in a diagonal direction with the first upper adjusting rod and having both ends coupled to the remaining pair of supporting shafts;
It includes a connection box coupled to the intersection of the first upper control rod and the second upper control rod,
The first upper control rod and the second upper control rod is a formwork device characterized in that the axial length is adjusted by screwing to move the support shaft to the support position and the separation position.

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