KR100746551B1 - The system and construction method to build apartment - Google Patents

Abstract

A construction method by climbing a form of a building is provided to construct a concrete wall simply and strongly by forming a steel form with a simple method using a form climbing system. The construction method by climbing a form of a building comprises the steps of: coupling a form climbing system attached with a 2-step worktable(50) using anchor bolts(11); completing a form by adhering a steel form(18) closely to a wall using a form forward/backward interlocking device of the form climbing system and adding an inner form, pouring concrete and curing a wall of the first floor; pulling out the steel form to the rear of the completed wall of the first floor using the form forward/backward interlocking device, ascending the 2-step worktable coupled with the steel form to the second floor using the form climbing system and fastening to the wall using anchor bolts; completing a form by advancing the climbed 2-step worktable and the steel form using the form forward/backward interlocking device and adhering closely to a wall and adding an inner wall steel form, pouring concrete and curing a wall of the second floor; pulling out the steel form to the rear of the completed wall of the second floor using the form forward/backward interlocking device, ascending the 2-step worktable coupled with the steel form to the third floor using the form climbing device and fastening to a wall using anchor bolts; installing 3 and 4-step worktables under the ascent 2-step worktable, advancing the steel form using the form forward/backward interlocking device and adhering closely to a wall, adding an inner form and pouring concrete, and then curing a wall of the third floor; and forming a concrete layer by ascending the steel form to the required floor by repeating above mentioned steps.

Description

The system and construction method to build apartment

1 is a view showing a conventional building method,

2 is a view sequentially showing a building construction method of the present invention,

3 is a view showing a foaming system of the present invention,

4 is an exploded view illustrating the upper elevating box of the present invention;

5 is an exploded view showing the lower lifting box of the present invention;

6 is a side view showing the interlocking means of the present invention;

7 is an exploded view showing the form elevating means of the present invention,

8 is a view showing the entire form elevating system of the present invention,

9 is a view illustrating a state in which the rising beam, the supporting beam, and the extension beam of the present invention are combined;

10 is a view showing the form lifting means of the present invention as viewed from the top.

<Brief description of the major symbols in the drawing shown>

One; Foundation concrete 10; Support beam

15; Rising beam 30; Upper lifting box

40; Lower lifting box 50; bench

51; Steel frame 60; Form interlocking means

70; Foam lifting means

The present invention relates to a construction method for constructing a building by raising the form of the building by magnetic force, and a form raising system thereof, and in particular, from the foundation concrete, the building rises while forming a rugged house using this rising system. It is structured in turn, but it is possible to raise it to the work table one by one without using a separate lifting means such as a crane. It is about the construction method of building and the form elevating system.

In general, in order to build a building, an exterior wall must be constructed. By the way, the conventional method of building the outer wall is to build a form by assembling a plurality of foam to form a form and to pour concrete mortar inside the curing. In addition, as the formwork method continues to evolve, it is excluded to form wall formwork to assemble one by one to hit one wall surface, and nowadays, a method of curing the wall surface by installing formwork is used. This method is very useful when it is used in apartments, piers and civil engineering to form large structures, which is more effective when the same type of wall is continuously raised to the second floor and the third floor.

Therefore, in the past, a crane for raising the large foam was indispensable to carry out such a process. In other words, in order to clearly describe the prior art will be described in detail based on the apartment building process. Many apartments are built on high floors. However, in the case of the outer wall, the shape of one layer, the shape of two layers, and the shape of the upper layer are all the same, and the size is often the same. Therefore, the foam used in the first floor must immediately rise to the second floor and form into a form again. When one layer is thus constructed and rises to another, the foam must be raised. However, these foams are considerable in size, and in order to provide firmness, they are often cast concrete using metal plates these days. Therefore, the weight weighs about 2-4 tons, and the tower crane A for raising the foam B has a limited capacity to lift the weight. Furthermore, if a strong wind blows during the ascent, the load that the tower crane must endure is greater. In addition, many sites where 20- or 30-storey apartments are built these days, when a large volume of foam is blown by high winds at high altitude, this can produce a huge problem.

For example, the tower crane fell and killed many people during the work of raising the foam at the construction site of the apartment. Therefore, the current construction process that has this problem was necessary to be developed.

The present invention, which solves the above problems, relates to a construction method for constructing a building while raising the form of the building by magnetic force, and a form raising system thereof. The structure of the high-rise building is sequentially structured, but it can be raised to the work platform one by one without using a separate lifting means such as a crane. It aims to provide a construction method of raising a building's form and its form elevating system.

Accordingly, the present invention provides a construction method for building a building by raising a form of a building, comprising the steps of: combining a form elevating system having a work platform of two stages with an anchor bolt to a foundation concrete; The second step: contacting the steel foam to the wall through the form back and forth interlocking means of the foam elevating system, the inner foam is padded to complete the gorge and pour concrete to cure the first floor wall; Step 3: Remove the steel foam through the form back and forth interlocking means behind the completed first floor wall, and raise the two-stage workbench combined with the steel foam to the second floor through the form elevating means and fasten it to the wall with anchor bolts. Wow; Fourth step: Two-stage workbench and steel foam raised to the second floor are advanced through the form back and forth interlocking means to be in close contact with the wall surface. Curing step; Step 5: Remove the steel foam through the form back and forth interlocking means behind the completed two-layer wall, raise the support beam through the form elevating means, and then combine the steel form with the steel form via the steel form elevating means. Elevating the work table to the third floor and fastening it to the wall with an anchor bolt; The sixth step: Install the three-stage and four-stage workbench under the two-stage workbench raised to the third floor, advancing the steel form with the form interlocking means, close to the wall, and pour concrete with the inner foam Curing the three-layer wall surface; Step 7: repeating steps 5 and 6 to form a concrete layer by raising the steel foam to the required layer; It is intended to provide a construction method of building by raising the form of the building in which the concrete is put up as it is attached to the concrete wall without the help of a separate tower crane by combining with each other.

In another aspect, the present invention provides a lifting system for raising a form of a building, comprising: a fastening flange coupled to an anchor bolt through concrete and a support beam fastened to the fastening flange; A rising beam that is bolted to the front of the support beam and is vertically high; An upper and lower lifting box surrounding the rising beam and being firmly fastened to the steel foam; A two-stage worktable fastened to an end of the steel foam and firmly fastened through a plurality of steel frames; Form front and rear interlocking means that is fastened to the side of the upper, lower elevating box to allow the steel form to interlock in the front and rear directions; A form elevating means provided in the elevating beam to elevate the steel form by interlocking the lower elevating box up and down; It is fastened to the front of the upper, lower lifting box is deformable steel foam that can be deformed to a desired width to be utilized as one side of the building girdle; Combined, but each of the separate rising beam and the support beam in an integrated state on the left and right ends of the steel form, respectively, these are fastened with the steel form through the upper and lower lifting boxes provided in the left and right pairs of the operation of the pump lifting means It is to provide a form elevating system that raises the workbench, and then raises the steel form to the desired height by elevating the beam and raising the form of the building to build the building.

The present invention is similar to the conventional one in that it relates to a construction method for elevating a building's form and its elevation system. However, it is a big feature that it can be used immediately when placing the first floor, and it does not need a separate climbing means to rise on its own wall, and accordingly, there is little possibility of heavy foam falling by wind. This will be described in detail with the drawings shown.

That is, in the present invention, as shown in FIG. 2A, the first step: coupling the form elevating system 100 to which the worktable 50 of the second stage is attached to the foundation concrete 1 using the anchor bolt 11 is performed. Go through the steps The base concrete (1) is projected to be somewhat projected to the upper part of the ground and the base concrete (1) is to mount the form elevating system 100 used in the present invention. The foam lifting system 100 is the support beam 10, the lifting beam 15, the upper and lower lifting boxes (30, 40), the work table 50, the foam front and rear interlocking means (60), the foam lifting means (70) And the iron foam 18 is provided in a combined state (a detailed structural description will be described later.) It is important here in the present invention that the form elevating system 100 can be mounted as soon as only the foundation concrete 1 is poured. .

Next, the present invention is the second step: the steel foam 18 is in close contact with the wall surface through the form back and forth interlocking means 60 of the form elevating system 100, and the inner foam 97 is padded to complete the The concrete 98 is poured to cure the one-story wall (shown in 2 of FIG. 2A). That is, the steel foam 18 is brought into close contact with the wall surface of the base concrete 1 through the form back and forth interlocking means 60 provided with the foam elevating system 100. Then, the steel foam 18 is standing upright in the space that becomes the wall surface of the first-floor residential space on the base concrete (1). On the other side, a separate inner foam 97 is padded to form an empty space. Therefore, the concrete is poured to the interior space of the giraffe to cure. Then a very solid concrete wall is formed, and since it is a whole steel form 18, it is poured without thickness variation (shown in 2 of FIG. 2A).

And the third step of the present invention is to remove the steel foam through the form back and forth interlocking means (60) to the rear of the finished one-layer wall surface and the work platform 50 of the second stage combined with the steel foam (18) form lifting means (70) 2) through the step of fastening to the wall surface anchor bolt (11). This is to remove the steel foam 18 from the concrete wall surface, as in the conventional concrete pouring method, as if to remove the gypsum from the generally poured and cured concrete wall surface. At this time, the present invention achieves through the form before and after the interlocking means 60, the detailed configuration and operation will be described later. Only, the whole steel foam 18 is separated from the concrete wall surface by detaching it rearward according to the interlocking method of the screw rotation (shown in 3 of FIG. 2A) and thus the steel foam 18 is formed on the first floor wall surface. After being separated, the work table 50 and the steel foam 18 are raised to the second floor through the form elevating means 70. Of course, the form elevating means (70) to achieve this will be described later, this form elevating means (70) is only a part of the form elevating system 100 of the two-stage work table 50 and the steel foam (18) The rising beam 15 and the support beam 10 are held in the state in which they are fastened to the anchor bolt 11 to the base concrete 1 (shown in 4 in FIG. 2B). As a result, the support beam 10 is firmly supported on the wall of the foundation concrete 1 through the anchor bolt 11 so that the support beam 10 is firmly supported and is supported by the work table 50 and the steel by the operation of the form elevating means 70. The foam 18 can be raised. This is very important in the present invention because the steel foam 18 and the work table 50 are substantial in weight. In addition, the support beam 10 and the rising beam 15 which are organically coupled thereto have a considerable weight. Thus, if all of these components are to be raised in combination, the load that the gas must bear will be great. However, if only the steel foam 18 and the work table 50 is raised first, and then the support beam 10 and the rising beam 15 are sequentially raised through the subsequent steps, the work burdening the weight is separated and the work is safe. It is convenient.

And the support beam 10 of the present invention is firmly fastened to the one-story concrete wall surface is cast and cured through the anchor bolt 11 at its lower end (shown in 5 of Figure 2b).

And the fourth step: the two-stage work table 50 and the steel foam 18 raised to the second floor is advanced through the foam front and rear interlocking means 60 to be in close contact with the wall surface, the inner wall steel foam (18) ) And pour the concrete in the state where the giraffe is completed and cures the second floor wall. As shown in 5 and 6 of Fig. 2b, the two-stage worktable 50 and the steel foam 18, which are first raised, are advanced through the form back and forth interlocking means 60, that is, the upper part of the one-layer concrete wall surface, that is, two The two-story concrete wall, which becomes a story residential space, is in close contact with the space to be poured. Standing vertically in the vertical upward direction of the first floor wall surface. And the inner foam 97 is also installed to complete the two-story wall girdle. Of course, at this time, the connection between the steel foam 18 and the inner foam 97 is achieved through a separator or a seperbolt penetrating them, and these configurations are later cut and buried in the concrete wall so as to more firmly support the concrete wall. It is. And the present invention, as shown in 6 of Figure 2b, the concrete is poured and cured to form a two-layer wall surface.

And the present invention is the fifth step: take out the steel foam 18 through the form back and forth interlocking means 60 to the rear of the completed two-layer wall surface, and raise the support beam 10 through the form elevating means 70 Then, after raising the two-stage working table 50 coupled with the steel form 18 through the steel form elevating means (70) to the third floor and undergoes the step of fastening to the wall surface with the anchor bolt (11).

That is, as shown in 7 of FIG. 2C, the steel foam 18 is retracted through the front and rear interlocking means 60 behind the two-layer wall surface. This is achieved through the front and rear interlocking means 60 in the same manner as described in the previous step, because such work must be performed to achieve the following after work. Meanwhile, the present invention raises the support beam 10 and the lift beam 15 through the form elevating means 70. The reason why such a rise is possible will be described in detail with reference to the configuration of the form elevating stage 70 which will be described later, but the steel form 18 through the lower elevating box 40 of the form elevating system 100. This is because it is firmly fastened to the concrete on the floor wall. That is, since the steel foam 18 and its two-stage worktable 50 are fixed to the two-layer wall through the anchor bolt 11, the support beam 10 and the support beam 10 are supported by the support. Can rise, as in FIG. 2C 7 shown. And when this rises, another extension beam 90 is bolted to the lower end of the support beam 10, the form elevating means 70 is operated again the steel form 18 and the second stage work table ( 50) is raised to three layers (shown in 8 of FIG. 2C). At this time, the raised steel foam 18 and the second stage work platform 50 are fastened through the anchor bolt 11 to the two-story concrete wall surface through the lower lifting box 40 which is raised at the same distance (as shown in 8 of FIG. 2C). .

And the sixth step of the present invention is to install a three-stage and four-stage workbench (95) under the two-stage workbench 50, which is raised to the third floor, the steel foam 18 to form the front and rear interlocking means 60 Adhering to the wall surface by advancing, the concrete is poured in a state where the inner foam (97) is padded and undergoes a step of curing the three-layer wall surface. That is, as shown in 8 of FIG. 2C, the steel foam 18 and the two-stage work table 50 of the present invention are already at the height of the third floor. The concrete walls of the first and second floors are already poured and cured. Therefore, extra work is often required for external structures. Therefore, in order to work on this structure, as shown in FIG. 2C of FIG. 2C, separate three-stage and four-stage working tables 95 are installed on the support beam 10 and the extension beam 90. Of course, the extension beam 90 is also firmly fastened to the concrete wall surface through the anchor bolt 11.

On the other hand, in the state set as described above, the form back and forth interlocking means 60 is operated to bring the steel foam 18 to advance to close contact with the wall surface. At this time, the steel foam 18 is a girdle for placing three layers. Then, concrete is poured into the space portion between the inner foam 97 and the steel foam 18 to cure the concrete wall surface of the third floor.

And the present invention repeats the seventh step: step 5 and step 6 and continues the step of raising the steel foam 18 to the required layer to form a concrete layer. In other words, this work can continue to the last floor of the apartment, for example the building to be built. Ascending and pouring in the same manner as described above. That is, this construction method is shown in detail in FIGS. 2d and f. And after all the concrete wall is poured, the work table 50 and the form elevating system 100 may be separately separated and seated on the ground through the tower crane, it may be lowered in a combined state.

As described above, the present invention is to vertically raise the steel foam 18, unlike the existing building method. In particular, the form rises through the system 100 to rise in itself. Rather than dangerously ascending through a tower crane to form a girdle, as in the prior art, the work table 50 and the steel foam 18 are raised while being supported by being fastened to a concrete wall that has already been poured. 10) and the rising beam 15 utilizes a weight division method of raising separately, the risk is extremely small.

Then, the configuration of the form front and rear interlocking means 60 of the second step will be described with reference to FIGS. 4 to 6.

That is, as shown, the upper and lower interlocking blocks 37 and 47 fastened to the upper and lower portions of the steel foam 18 and the upper and lower interlocking boxes 30 and 40, respectively, rising on the upper and lower interlocking blocks 37 and 47. And the interlocking screws 36 and 46 of the upper and lower parts penetrating the front and rear interlocking blocks 37 and 47 and protruding through the side screw plates 35 and 45 of the upper and lower lifting boxes 30 and 40, respectively. And, there is a front and rear interlocking portion consisting of the upper and lower rotation knobs 63 fastened to the end of the interlocking screw (36, 46), the connection connecting the sprockets 64 fastened to the interlocking screw (36, 46) of the interlocking unit There is a chain 65. Therefore, when the rotary knob 63 of one side is rotated, the interlocking screw 36 rotates, but the interlocking screw 36 of the other side connected to the connecting chain 65 also rotates the same number, and the steel foam 18 is moved back and forth. To move in the direction.

In more detail, the form back and forth interlocking means 60 is a means for placing the concrete wall surface while moving the steel foam 18 in the front-rear direction, and pulling it out of the concrete wall surface for ascension. In the present invention, this operation is achieved through the rotation of the interlocking screw (36, 46), the screw plate (35, 45) is fixed to the side of the upper, lower lifting box (30, 40) shown and the screw plate ( The interlocking screws 36 and 46 are penetrated through 35 and 45, and the rotary knob 63 is attached to the end thereof. Therefore, if the rotary knob 63 is rotated, the interlocking screws (36, 46) is rotated and the forward and backward interlocking along the thread. At this time, the front and rear interlocking blocks 37 and 47 are fastened to the other end of the interlocking screws 36 and 46, and the front and rear interlocking blocks 37 and 47 are bolted to the steel foam 18. Therefore, the interlocking of the front and rear interlocking blocks 37 and 47 is the interlocking of the steel foam 18. That is, when the operator rotates the rotary knob 63 to interlock the interlocking screws 36 and 46, the interlocking blocks 37 and 47 fixed at the ends thereof move in the forward and backward directions while holding the steel foam 18. It works. On the other hand, such a configuration is mounted on both the upper, lower lifting box (30, 40) as shown. The reason is that the steel foam 18 has a long width and height, so only one side is fastened and cannot be interlocked with each other. Therefore, in the present invention, the rising beam 15 and the support beam 10 corresponding to each other are formed on the left and right sides, and the upper and lower lifting boxes 30 and 40 are provided on both the left and right rising beams 15. Therefore, the upper and lower lifting boxes (30, 40) used in the system of the present invention is to be used in combination of a total of four each two.

Then, in order to make the description easier, look at the operation through the front and rear interlocking means (60) fastened to the upper, lower lifting boxes (30, 40) only one side. That is, when the operator rotates the rotary knob 63 coupled to the lower lifting box 40, the interlocking screw 46 is rotated and a separate sprocket 64 is fixed to the interlocking screw 46. . And this sprocket is also fastened to the interlocking screw 36 coupled to the upper lifting box 30. And as shown in the figure, the long connecting chain 65 is wound between the sprocket. Therefore, when the lower interlocking screw 46 on one side rotates, the upper interlocking screw 46 on the other side also rotates due to the coupling of the sprocket 64 and the connecting chain 65. As a result, the steel foam 18 is upper. The lower part and the same forward and backward. Of course, if the form back and forth interlocking means 60 formed on the left rising beam 15 is operated, the form back and forth interlocking means 60 mounted on the rising beam 15 formed on the right side performs the same operation. Link to.

In the present invention, a means for raising the work table 50 and the steel foam 18 and raising the rising beam 15 and the support beam 10 is configured separately. That is, it is a structure for raising a system in each step. Therefore, this configuration and its operation will be described in detail.

The form elevating means 70 of the third step, as shown in the figure, there is a rotary motor 72 to which the reducer 71 is attached, and a long vertical screw thread connected through the reducer shaft and the chain 73. There is 61. In addition, there is a lower lifting box 40 to which the lifting nut 62 to which the vertical threaded screw 61 is inserted and screwed is fastened. Therefore, by combining with each other to rotate the screw 61 through the rotation of the rotary motor 72, the rotation of the vertical screw screw 61 to raise the lower lifting box 40 is fixed to the lifting nut 62 In addition, the lower elevating box 40 is to be raised together with the steel foam (18).

That is, as shown, the form elevating means 70 of the present invention is the driving means for raising the work table 50 and the steel foam 18, and then raising the rising beam 15 and the support beam 10 All. In order to operate the form elevating means 70, the rotary motor 72 rotates, and the reducer engaged with the gear rotates according to the rotation. Of course, when the reducer 71 rotates, the sprocket coupled to the shaft rotates and the sprocket rotates to wind the chain 73. The chain 73 rotates the sprocket on the other side, and the screw 61 rotates because the sprocket is coupled to the screw 61. Therefore, the screw 61 rotates to raise and lower the lifting nut 62 coupled to the vertical thread. That is, the rotational movement of the screw 61 serves to interlock the lifting nut 62 up and down. In this case, the lifting nut 62 is firmly fastened to the lower lifting box 40, and the lower lifting box 40 is lowered because the work table 50 and the steel form 18 are fastened. The nut 62, the lower lifting box 40, the work table 50 and the steel foam 18 rises at the same distance.

As a result, the iron foam 18 is raised through the rotation of the rotary motor 72 of the present invention. In FIG. 2, after the steel foam 18 is raised, the lifting beam 15 and the supporting beam 10 may be lifted. In this case, the following operation is achieved.

That is, when the steel foam 18 and the work table 50 rises, since the support beam 10 and the lift beam 15 are firmly fastened to the concrete wall by the anchor bolt 11, the form elevating means 70 Although it rises by the rotation of the in-rotating motor 72, once the steel foam 18 and the work table 50 is firmly fastened to the concrete wall surface through the anchor bolt 11 is impossible to move.

After the steel foam 18 and the work table 50 are fastened with the anchor bolt 11, the lifting beam 15 and the support beam 10 are unscrewed from the anchor bolt 11. And the operator rotates the rotary motor 72 in the reverse direction. Then, the screw 61 also rotates, and the lifting nut 62 will try to interlock. However, the lifting nut 62 is fastened to the steel foam 18 in a state of being coupled to the lower lifting box 40 is attached to the concrete wall surface. Therefore, the lifting nut 62 is fixed, so that the screw 61 comes up. At this time, since the screw 61 is fixed to the rising beam 15, the rising beam 15 and the supporting beam 10 are raised to increase the thickness by one layer.

And this invention does not only request such a construction method. The form elevating system 100 used in the construction method is also the subject of the claim. Therefore, the configuration and operation will be described in detail with the drawings shown.

That is, the present invention in the lifting system for raising the form of the building, there is a fastening flange 12 coupled to the concrete through the anchor bolt 11 and the support beam 10 fastened to the fastening flange 13 and In addition, there is a rising beam 15 that is bolted to the front of the support beam 10 and is vertically high. In addition, the upper and lower lifting boxes 30 and 40 are wrapped around the rising beam 15 and firmly fastened to the steel foam 18, and are fastened to the ends of the steel foam 18 to form a plurality of steel frames 51. There is a two-stage workbench 50 that is firmly fastened through). And there is a form before and after interlocking means 60 is fastened to the sides of the upper and lower lifting boxes 30, 40 to link the steel foam 18 in the front and rear direction, the rising beam 15 inside There is a form elevating means (70) for raising and lowering the steel form by interlocking the lower elevating box (40) up and down. And it is fastened to the front of the upper and lower lifting boxes 30, 40 is formed of a steel foam 18 that can be deformed to a desired width to be utilized as one side of the building's girdle. Therefore, each of the rising beam 15 and the support beam 10 in an integrated state on each of the left and right ends of the steel foam 18, and the upper and lower lifting boxes (30, 40) provided with these in the left and right pairs Is coupled to the steel form 18 through the operation of the pump lifting means 70 to raise the work table 50, and then to raise the beam to raise the steel form 18 to the desired height to build the building will be.

That is, the foam lifting system 100 of the present invention is largely support beam 10, rising beam 15, upper and lower lifting boxes 30, 40, work table 50, form back and forth interlocking means 60, form lifting means 70 and the iron foam 18 are combined. In the configuration thereof, the support beam 10 and the rising beam 15 are bolted together, and the upper and lower lifting boxes 30 and 40 are coupled around the outer circumferential surface of the rising beam 15. to be. And the iron foam 18 is coupled to the lower lifting box 40. And the work table 50 is fastened to the steel foam 18, the foam front and rear interlocking means 60 is fastened to the lower elevating box 40 and the upper elevating box (30). And the form elevating means 70 is embedded in the rising beam 15 to operate. In addition, since the detailed operation of this configuration is described in detail through the above-described construction method, detailed descriptions thereof will be omitted.

Furthermore, the present invention wraps around the rising beam 15 and the upper elevating box 30 which is firmly fastened to the steel foam 18 is formed of a plurality of guide rolls installed inside the guide panel 31 on the front side by a combination of metal plates ( 32), and is coupled to the end of the interlocking screw 36 screwed to the screw plate 35 to the side plate 34 of the body 33 of the upper elevating box 30 is integrally combined with the steel foam (18) There is an interlocking block 37. In addition, there is a body 33 which is a combination of a metal plate provided in a state having a space 38 therein, the guide roll 39 is provided in the horizontal direction inside the body 33 to guide the rising beam 15 Is formed. Therefore, it is rising with the steel foam 18 to be raised. As described above, the upper lifting box 30 has a plurality of guide rolls 32 formed inside the guide panel 31 as shown in FIG. 4. Therefore, if the form back and forth interlocking means (60) of the present invention is operated to interlock the front and rear interlocking blocks (37, 47) coupled to the iron foam (18), the guide roll 32 can be smoothly interlocked To induce. And since the guide roll 39 is shown in the interior of the body 33 is coupled to the metal plate is coupled to the smoother interlocking movement when the ascending beam 15 moves up and down the guide roll 39 To be possible.

Of course, there are other bearings to assist the rotation of the guide roll 39, but this is a known configuration and the fastening structure will be.

Meanwhile, the lower lifting box 40 similar to the upper lifting box 30 of the present invention is fastened to the rising beam 15 of the present invention, and the screw is fastened through the lifting nut 62. Then this lower lifting box 40 will be described in detail. That is, as shown in Figure 5, the lower lifting box 40 is wrapped around the rising beam 15 and firmly fastened to the steel foam 18, a plurality of metal plate is installed inside the guide panel 41 in the front of the coupling There is a guide roll 42, is fastened to the end of the interlocking screw 46 screwed to the screw plate 45 to the side plate 44 of the lower lifting box 40 body 13 integrally with the steel foam (18) There is a front and rear interlocking block 47 to be coupled. In addition, there is a body 43 which is a combination of a metal plate provided in a state having a space 48 therein, a plurality of guide rolls which are provided in the body 43 in a horizontal direction to guide the rising beam 15 ( 49) In addition, a lifting nut 62 is formed in which the vertical thread screw 61 penetrated integrally with the body 43 and screwed therein is coupled to the body 43.

Therefore, when the lifting nut 62 rises by the rotation of the vertical screw screw 61 in combination with each other, the lifting nut 62 rises together with the steel foam 18 integrally coupled thereto.

As a result, the lower lifting box 40 is similar in shape to the upper lifting box 30, but is screwed to the screw 61 through the lifting nut 62 fastened to the inside of the body 43. There is a difference in that it is the same in that it is coupled with the steel foam 18 through the front and rear interlocking block (47). Of course, the reason why the separate lifting nut 62 is not fastened to the upper elevating box 30 is that the upper elevating box 30 is raised to some extent with the steel foam 18 according to the rotational movement of the screw 61. This is to make it easy to ascend with a clearance.

In addition, the present invention has the foam front and rear interlocking means 60 and the foam lifting means 70. Of course, this is the same as the form back and forth interlocking means 60 described in the above-described construction method, so only the configuration is listed and the description of its operation is refrained. That is, the form before and after the interlocking means 60 of the present invention, the front and rear interlocking blocks 37 and 47 fastened to the upper and lower portions of the steel foam 18, respectively, and the upper and lower interlocking blocks 37 and 47 are placed on the image to rise. The upper and lower parts of the lower elevating boxes 30 and 40 and the front and rear interlocking blocks 37 and 47 protruding through the side screw plates 35 and 45 of the upper and lower elevating boxes 30 and 40, respectively. There is a front and rear interlocking portion consisting of the interlocking screw (36, 46) and the upper and lower rotation knob 63 fastened to the ends of the interlocking screw (36, 46), the sprocket fastened to the interlocking screw (36, 46) of the interlocking screw There is a connecting chain 65 connecting 64 with each other. Accordingly, when the rotation knob 63 of the one side is coupled to each other to rotate, the interlocking screw 36 rotates, but the interlocking screw 36 on the other side connected to the connecting chain 65 also rotates the same number of steel foams 18. ) Is moved forward and backward.

In addition, the above-described form elevating means 70, there is a rotary motor 72 to which the reducer 71 is attached, and has a long vertical screw screw 61 connected through the reducer shaft and the chain 73. In addition, there is a lower lifting box 40 to which the lifting nut 62 to which the vertical threaded screw 61 is fitted is screwed. Therefore, by combining with each other to rotate the screw 61 through the rotation of the rotary motor 72, the rotation of the vertical screw screw 61 to raise the lower lifting box 40 is fixed to the lifting nut 62 In addition, the lower elevating box 40 is to be raised together with the steel foam (18).

Meanwhile, in the present invention, the fastening flange 12 coupled to the concrete through the anchor bolt 11 forms a separate fastening hole to fasten the support beam 10 only when necessary using the fastening bolt 82. It is preferable. That is, by inserting the fastening bolt 82 in the fastening hole formed in the fastening flange 12 and combines it with the support beam 10 to achieve a firm coupling. Therefore, when the support beam 10 is to be raised, after loosening the fastening bolt 82 of the fastening hole, ascending, the anchor bolt 11 and the fastening flange 12 and the support beam ( 10) can be tightened.

In addition, when the building is constructed in three or more floors, the support beam 10, and can be used by fastening a separate extension beam 90, the second stage work table 50, a separate two-stage work table It is preferable to be able to tighten and use 95. Here, the installation of the extension beam 90 is to maintain the robustness even if the separate two-stage workbench 95 is installed, and when building a high building, install the extension beam 90 for a solid support The extension beam 90 is also for fastening firmly with the concrete wall.

In addition, it is also a feature of the present invention to form and couple a cover plate to the outside of the rising beam in the illustrated figure. The reason why the cover plate is combined is to protect the screw 61 and the form elevating means 70 in a dusty construction site.

As described above, the present invention is easy to construct and use a solid concrete wall construction because the construction method is easy to rise and rise on the concrete wall of the self-pouring building to form a steel foam by raising the foam elevating system in a simple way that the screw is rotated Do.

In addition, the present invention is a high sense of stability that can prevent the accidental falling accidents blown by the wind because it does not need to raise the heavy iron foam through a separate tower crane.

Claims (11)

In construction method to raise form of building, and to build, First step: coupling the form elevating system (100) attached to the two-stage working table (50) to the foundation concrete (1) using the anchor bolt (11); Second step: the steel foam 18 is in close contact with the wall through the form back and forth interlocking means 60 of the foam elevating system 100, and the inner foam 97 is padded to complete the girdle and pour concrete 98 Curing the one-layer wall surface; Step 3: Remove the steel foam through the form back and forth interlocking means (60) to the rear of the finished one-layer wall surface and the work platform 50 of the two stages combined with the steel form 18 through the form elevating means (70) Ascending to the layer and fastening to the wall surface with the anchor bolt (11); Fourth step: the two-stage work table 50 and the steel foam 18, which are raised to the second floor, are advanced by the front and rear interlocking means 60 to be in close contact with the wall surface, and the inner wall steel foam 18 is padded. Curing the second floor wall by pouring concrete in a state where the giraffe is completed; Step 5: After removing the steel foam through the form back and forth interlocking means 60 and raising the support beam 10 through the foam lifting means 70, the steel foam lifting means ( 70) the two-stage worktable 50 coupled with the steel foam 18 to the third floor to be fastened to the wall with the anchor bolt (11); Step 6: Install the workbench 95 of the third and fourth stages under the workbench 50 of the second stage raised to the third floor, and advance the steel form 18 to the wall surface by the form back and forth interlocking means 60. In close contact with the inner foam 97 and pouring concrete to cure the three-layer wall surface; Step 7: repeating steps 5 and 6 to raise the steel foam 18 to the required layer to form a concrete layer; Construction method of building by raising the form of the building, characterized in that the concrete is poured by rising to the state attached to the concrete wall without the help of a separate tower crane by combining with each other. The method of claim 1, Form the front and rear interlocking means 60 of the second step, The upper and lower interlocking blocks 37 and 47 fastened to the upper and lower portions of the steel foam 18, and the upper and lower elevation boxes 30 and 40, which are mounted on the upper and lower interlocking blocks 37 and 47, and rise. Interlocking screws 36 and 46 of the upper and lower parts penetrating the blocks 37 and 47 and protruding through the side screw plates 35 and 45 of the upper and lower lifting boxes 30 and 40, and the interlocking screw 36 46) front and rear interlocking portion consisting of upper and lower rotation knobs 63 fastened to the end; A connecting chain 65 connecting the sprockets 64 fastened to the interlocking screws 36 and 46 of the front and rear interlocking portions; When combined with each other to rotate the rotation knob 63 of the one side the interlocking screw 36 is rotated, but the other interlocking screw 36 connected to the connection chain 65 also rotates the same number of steel foam (18) Construction method of building by raising the form of the building, characterized in that to move in the front and rear direction. The method of claim 1, The form elevating means 70 of the third step, A rotary motor 72 to which a reducer 71 is attached; A long vertical screw screw 61 connected to the reducer shaft through a chain 73; A lower lifting box 40 to which the lifting nut 62 to which the vertical threaded screw 61 is fitted is screwed; In combination with each other to rotate the screw 61 through the rotation of the rotary motor 72, the rotation of the vertical screw screw 61 to raise the lower lifting box 40, the lifting nut 62 is fixed, Construction method by raising the form of the building, characterized in that the lower lifting box 40 is also combined with the steel foam (18) is combined. In the climbing system to raise the form of the building, A fastening flange 12 coupled to the anchor bolt 11 to the concrete and a support beam 10 fastened to the fastening flange 13; A rising beam 15 which is bolted to the front of the support beam 10 and is vertically high; An upper and lower lifting boxes 30 and 40 wrapped around the rising beam 15 and firmly fastened to the steel foam 18; A two-stage worktable 50 fastened to an end of the steel foam 18 and firmly fastened through a plurality of steel frames 51; Form front and rear interlocking means 60 is fastened to the sides of the upper and lower lifting boxes 30 and 40 to allow the steel form 18 to interlock in the front and rear directions; A form elevating means (70) provided in the elevating beam (15) to elevate the steel form by interlocking the lower elevating box (40) up and down; It is fastened to the front of the upper, lower elevating box (30, 40) is a steel foam (18) that can be deformed to a desired width to be utilized as one side of the building's girdle; Combined, but each of the separate rising beam 15 and the support beam 10 in an integrated state on the left and right ends of the steel foam 18, respectively, these are provided in the left and right pairs of the upper and lower lifting boxes (30, 40) It is fastened to the steel form (18) through the operation of the pump lifting means (70) to raise the work table 50, and then to raise the beam to raise the steel form (18) to the desired height to build the building A form elevating system that builds up the building's form, characterized by building. The method of claim 4, wherein The upper lifting box 30 surrounding the rising beam 15 and being firmly fastened to the steel foam 18, A plurality of guide rolls 32 installed inside the guide panel 31 on the front side by combining metal plates; Front and rear interlocking block (37) which is fastened to the end of the interlocking screw (36) screwed to the screw plate (35) on the side plate (34) of the body (33) of the upper elevating box (30) and integrally combined with the steel foam (18). )and; A body 33 which is a combination of a metal plate provided with a space 38 therein; A guide roll 39 provided in the horizontal direction in the body 33 to guide the rising beam 15; Form elevating system for building by raising the form of the building, characterized in that rising with the steel foam (18) to be combined to rise. The method of claim 4, wherein The lower lifting box 40 surrounding the rising beam 15 and firmly fastened to the steel foam 18, A plurality of guide rolls 42 installed in the guide panel 41 on the front side by combining the metal plates; Front and rear interlocking block 47 is fastened to the end of the interlocking screw 46 screwed to the screw plate 45 to the side plate 44 of the lower elevating box 40 body 13 integrally combined with the steel foam (18) and; A body 43 which is a combination of a metal plate provided in a state having a space 48 therein; A plurality of guide rolls 49 arranged in a horizontal direction in the body 43 to guide the rising beam 15; A lifting nut 62 in which the vertical threaded screw 61 which is integrally fastened to the body 43 and penetrated therein is screwed into the body 43; When the lifting nut 62 is coupled to each other and rises by the rotation of the vertical screw screw 61, the foam lifting system for raising and building the foam of a building, characterized in that it rises together with the steel foam 18 coupled integrally. . The method of claim 4, wherein The front and rear interlocking means 60, The upper and lower interlocking blocks 37 and 47 fastened to the upper and lower portions of the steel foam 18, and the upper and lower elevating boxes 30 and 40 which are mounted on the upper and lower interlocking blocks 37 and 47, and the upper and lower interlocking blocks 37 and 47 respectively. Interlocking screws 36 and 46 of the upper and lower parts penetrating the blocks 37 and 47 and protruding through the side screw plates 35 and 45 of the upper and lower lifting boxes 30 and 40, and the interlocking screw 36 46) front and rear interlocking portion consisting of upper and lower rotation knobs 63 fastened to the end; A connecting chain 65 connecting the sprockets 64 fastened to the interlocking screws 36 and 46 of the front and rear interlocking portions; When combined with each other to rotate the rotation knob 63 of the one side the interlocking screw 36 is rotated, but the other interlocking screw 36 connected to the connection chain 65 also rotates the same number of steel foam (18) A form elevating system for elevating and building a building's form, which moves the building in front and rear directions. The method of claim 4, wherein The form elevating means 70, A rotary motor 72 to which a reducer 71 is attached; A long vertical screw screw 61 connected to the reducer shaft through a chain 73; A lower lifting box 40 to which the lifting nut 62 to which the vertical threaded screw 61 is fitted is screwed; In combination with each other to rotate the screw 61 through the rotation of the rotary motor 72, the rotation of the vertical screw screw 61 to raise the lower lifting box 40, the lifting nut 62 is fixed, The form elevating system for building by raising the form of the building, characterized in that the lower elevating box 40 is combined with the steel foam (18) is also elevated. The method of claim 4, wherein Fastening flange 12 is coupled to the concrete through the anchor bolt 11, Form rising system for building the form of the building, characterized in that formed by a separate fastening hole (81) by using a fastening bolt 82, detachable to fasten the support beam 10 only when necessary. The method of claim 4, wherein In the support beam 10, When the building is constructed in three or more floors, a form elevating system for raising and building the form of the building, characterized in that the use of a separate extension beam (90) by fastening. The method of claim 4, wherein To the bottom of the second stage work table 50, Form elevating system for building by raising the form of the building, characterized in that can be used by fastening a separate two-stage worktable (95).

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