KR101252427B1 - Exhibition space slab new construction structure having finishing mold and construction method of the same - Google Patents

Abstract

PURPOSE: An expansion structure for a floor slab or a large scale exhibition space including a finishing mold is provided to improve the workability and reduce the installation costs by increasing the joint gap and the area of the concrete floor slab. CONSTITUTION: An expansion structure for a floor slab or a large scale exhibition space including a finished mold comprises an underground support slab(14), an elastic pad(16), a concrete floor slab(12), a cushion plate(18), a sleeve plate(20), a finishing mold(22), an elastic sealant(24), and a mortar layer(30a,30b). The underground support slab is installed in the lower part of the joint generated between the gaps of the adjacent concrete floor slabs. The elastic pad supports the concrete floor slab with an elastic repulsive power. The concrete floor slab is installed in the elastic pad and comprises of a cast in place of the concrete or precast concrete. The cushion plate is installed in a support protrusion(112) of the concrete floor slab. The sleeve plate is installed in the upper part of the cushion plate. The finishing mold is connected to the sleeve plate, and the elastic sealant is inserted inside the finishing mold. The mortar layer is cured in the divided space around the finishing mold and lays the sleeve plate.

Description

Exhibition space slab new construction structure having finishing mold and construction method of the same}

The present invention relates to a large-scale exhibition space floorboard expansion and contraction structure and a construction method having a finishing mold, in particular, can greatly increase the area and joint spacing of the concrete floorboard can reduce the installation cost and improve the construction, SOG The present invention relates to a large-scale exhibition floor deck structure and a construction method having a finishing mold that can be used without settling of the ground.

Even if there is no foundation under the floor, there is a Slab on Grade (hereinafter referred to as SOG) method used after compaction. The SOG method is a method in which concrete is poured and slab construction is performed immediately after strengthening the rubble compaction on the original ground without piles, and is sometimes applied to the floor of the exhibition space.

These SOG slabs are advantageous for forming large exhibition spaces. However, SOG slab is made of concrete and should be constructed in consideration of the change in temperature. Typically, expansion joints are constructed during flooring.

At this time, SOG slab should satisfy the strength of (1) 210Kg / cm ² or more, (2) 2000kg / m ² equal distribution load with minimum thickness of 4inch or more, and the required thickness (SOG) should be at least 150mm, (3) The maximum area of the crack control joint is defined as 55.7 m ² (600 ft ² ) (approximately 25 ft (7.62 m) of joint spacing).

In general, the slab is constructed on the compaction ground 5 by connecting the hinge bar 102 at the joint with the bottom plate 100 and the bottom plate 100 adjacent to each other as shown in FIG.

However, the slab has a problem that breakage or settlement occurs frequently due to concentrated load or equipment wheel load due to discontinuities in the joint. It also has the disadvantage of increasing the installation cost, which can not significantly increase the joint spacing.

As a background technology of the present invention, Korean Patent Registration No. 10-0702687 (joint of a structure and a method of forming the same) is proposed. It is separated with a lower gap of a certain interval, the structure having an upper end of the connection to the upper edge of the upper gap wider than the lower gap and having one or more grooves parallel to the gap on the bottom surface of the upper gap; A backup material positioned below the upper end of the lower gap and inserted to form a filling space in an upper portion of the lower gap; A backup material filler filling the filler space with a filler to an upper surface of the lower gap; A flat plate-shaped support plate coupled to a portion of the top gap bottom surface and the filling portion and having a concave-convex pattern on the surface thereof while exposing a recess of the bottom surface of the upper gap; And a joint filling part formed by filling the upper portion of the support plate, the recess, and the upper gap with the filler to the upper surface of the structure.

However, the background art focuses on the durability of the joint part, and thus it is difficult to cope with the expansion and contraction according to the temperature change of the structure. That is, there is no means to absorb it upon temperature expansion of the structure. Therefore, it is difficult to increase the spacing of the joint (joint part) or the area of the structure, and thus the construction cost cannot be reduced.

Korea Patent Registration No. 10-1078363 Korea Patent Registration No. 10-0966530

The present invention can greatly increase the area and joint spacing of the concrete floorboards to reduce the installation cost and improve the constructability, and the large-scale exhibition space floorboard stretch structure having a finishing mold that can be used in the SOG form without settlement of the ground and The purpose is to provide the construction method.

The large scale exhibition space floorboard stretching structure having a finishing mold according to an appropriate embodiment of the present invention,

An underground support slab fabricated by in-situ or precast concrete and positioned on the lower side of the joint formed between the gaps of the adjacent concrete slabs and supported on the rubble compaction layer;

An elastic pad having elastic repulsive force spaced apart from each other on an upper surface of the base support slab to support the concrete deck;

A concrete bottom plate made of cast-in-place or precast concrete and supported by an elastic pad by forming a supporting jaw to create a mortar filling space having a predetermined depth and a predetermined width in a longitudinal direction at an end thereof;

A cushion plate fixed to the support jaws on both sides by anchor bolts;

A sleeve plate having one end fixed to one cushion plate and the other end thereof being in surface contact with the other cushion plate;

A closing mold having one end fixed to the other end of the sleeve plate to divide the mortar filling space into two sides;

An elastic rod material inserted into the finishing mold; And

It is characterized in that it comprises a mortar layer which is cured in the divided space around the finishing mold to embed the sleeve plate.

In addition, the closing mold is the upper corrugated plate having a corrugated shape to facilitate expansion deformation, one side plate bent vertically at one end of the upper corrugated plate, the other plate bent vertically at the other end of the upper corrugated plate, bent at right angles at the other plate And a plurality of studs joined to one side diaphragm, a sealing material receiving space portion formed between the two side diaphragms.

In addition, the sleeve plate is characterized in that the construction is made of fiber-reinforced plastic.

In addition, the cushion plate is characterized in that the construction is made of fiber-reinforced plastic.

In addition, the elastic sealing material is characterized in that made of rubber having a rectangular cross section.

According to the large-scale exhibition space floorboard expansion and construction method having a finishing mold according to an embodiment of the present invention,

Installing an underground support slab which is made of in-cast or precast concrete and is positioned on the lower side of the joint formed between the gaps of the adjacent concrete decks and is supported by the rubble compaction layer;

Installing elastic pads spaced apart from each other on an upper surface of the base support slab to support the concrete deck;

It is made of cast-in-place or precast concrete and forms a support jaw to create a mortar filling space part with a certain depth and a certain width in the longitudinal direction at the end. Supporting;

Fixing one end of the sleeve plate to one support jaw and making the other end of the sleeve plate contact the upper surface of the other support jaw;

Placing the elastic sealing material inside the closing mold, and fixing the finishing mold to the other end of the sleeve plate to divide one side mortar filling space into two sides;

It is characterized in that the construction through the step of embedding the sleeve plate by curing mortar in the divided space around the finishing mold.

According to the large-scale exhibition space floorboard expansion and contraction structure with the finishing mold of the present invention and its construction method, it is possible to prevent cracks or breakage of the joint because the concentrated load is supported by the elastic pad at the point portion. In addition, the sleeve plate freely slides in response to the expansion and contraction of the concrete floor plate according to the temperature change, thereby responding to the change of the clearance.

Therefore, the joint spacing can be greatly increased, thereby reducing installation costs and improving workability. In addition, SOG has the advantage that large space can be used without ground subsidence.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
1 is a block diagram of a large-scale exhibition space floorboard stretch structure having a closing mold according to the present invention.
Figure 2 is an exploded perspective view of the closing mold and elastic sealing material applied to the present invention.
Figure 3 is a perspective view of the cushion plate applied to the present invention.
4 to 7 is a process chart showing the construction of a large scale exhibition space floorboard expansion method having a finishing mold according to the present invention.
8 is a construction conceptual view of a general large space slab.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

< Closing mold  Having a large exhibition space Bottom plate  Stretch Structure>

The stretchable structure of a large exhibition space floor plate according to the present invention is shown in FIG. As shown in FIG. 1, the ground support slab 14 is provided on the lower side of the joint formed between the gaps between the adjacent concrete deck plates 12 and 12. Underground slab 14 is produced by in-situ or precast concrete. The ground support slab 14 is constructed after forming the rubble compaction layer 6 compacted with rubble on the compaction ground 5. At this time, the base bearing slab 14 is manufactured to have sufficient strength to support the load of various equipment or structures installed in the large space.

Elastic pads 16 and 16 are installed on the upper surface of the base bearing slab 14. The elastic pads 16 and 16 are spaced apart from each other to support the slabs 12 and 12 to support the concrete base plates 12 and 12 with elastic repulsive force. In this case, the elastic pads 16 and 16 are made of rubber and have the same thickness, width, and length.

Concrete bottom plates 12 and 12 are installed on the elastic pads 16 and 16. Concrete decks 12 and 12 are made of cast-in-place or precast concrete. At this time, the concrete base plate (12, 12) is to support the support jaw (122, 122) so as to create a mortar filling space (121, 121) (see Fig. 6) having a predetermined depth (h) and a predetermined width (w) in the longitudinal direction at the end The cushion plates 18 and 18 are formed in the support jaw 122 and 122 of both sides. The cushion plates 18 and 18 are fixedly installed on the concrete bottom plates 12 and 12 via the studs 19. The cushion plates 18 and 18 may be made of metal or preferably made of fiber reinforced plastic (FRP) that does not rust in water.

The sleeve plate 20 is installed on the upper surfaces of the cushion plates 18 and 18. The sleeve plate 20 is in surface contact with the upper surfaces of the cushion plates 18 and 18. At this time, one end of the sleeve plate 20 is fixed to one side cushion plate 18 through the anchor bolt 21. Accordingly, the other end of the sleeve plate 20 is in surface contact with the other cushion plate 18 to allow relative sliding movement to each other. The sleeve plate 20 may be made of metal, but preferably, may be made of fiber reinforced plastic (FRP) that does not rust in water.

The other end of the sleeve plate 20 is the closing mold 22 is connected to the fastening means (23). Finishing mold 22 may be made of synthetic resin or steel. The closing mold 22 divides the mortar filling space 121 into both sides.

The closing mold 22 has an upper corrugated plate 221 having a corrugated shape, one side plate 222 vertically bent at one end of the upper corrugated plate 221, and an upper corrugated plate 221 as shown in FIG. 2. The sealing plate accommodating space portion 225 formed between the other side plate 223, the flange 224 bent at right angles at the other plate 223, the two side plates 222, 223 vertically bent at the other end of the other end ( And a plurality of studs 226 joined to 222.

The elastic sealing material 24 is inserted into the sealing material storage space 225 of the finishing mold 22. At this time, the bottom surface of the elastic sealing material 24 is installed to be in close contact with the upper surface of the other cushion plate 18.

Mortar layers 30a and 30b cured with mortar are formed in the divided space around the finishing mold 20. Therefore, the sleeve plate 20 is embedded by the mortar layers 30a and 30b.

The stretch structure of the large-scale exhibition space floor plate is such that the elastic pad 16 supported on the upper surface of the concentrated support slab 14 absorbs the load even when the concrete floor plates 12 and 12 are subjected to the concentrated load by the exhibition structure. This prevents the occurrence of cracks or breakage.

In addition, when the concrete bottom plate (12, 12) is inflated / contracted due to temperature changes, the behavior that the upper corrugated plate 221 and the elastic sealing material 24 of the finishing mold 22 is forcibly contracted / expanded at the same time Happens. Therefore, it corresponds to the change in the joint clearance G between the concrete slabs 12 and 12.

At this time, a slip phenomenon occurs between the free end of the sleeve plate 20 (not fixed with anchor bolts) and the other cushion plate 18 to prevent expansion and contraction of the concrete floor plates 12 and 12. I never do that.

As described above, according to the present invention, the elastic bar sealing material 24 shrinks and expands and recovers according to the temperature change of the concrete bottom plates 12 and 12, and at the same time, the sleeve plate 20 slides on the other cushion plate 18. Therefore, the clearance between the concrete slabs 12 and 12 corresponds to the stretching change, and the mortar layers 30a and 30b are prevented from cracking or breaking.

< Closing mold  Having a large exhibition space Bottom plate  Construction method of extension structure>

The method for constructing a large-scale exhibition floor deck construction including the finishing molding will be described sequentially.

First, the compaction ground 5 is formed by compacting the ground from the lower portion to the upper portion as shown in FIG. 4, and the rubble compaction layer 6 is formed by uniformly compacting the rubble on the compaction ground 5.

Next, the underground support slab 14 is installed as shown in FIG. The underground support slab 14 is installed on the rubble compaction layer 6 so as to be located at the lower side of the joint formed between the gaps between the adjacent concrete deck plates 12 and 12.

Next, elastic pads 16 and 16 are installed. The elastic pads 16 and 16 are spaced apart from each other on the upper surface of the base support slab 14 to support the slabs 14 and 14. The elastic pads 16 and 16 are used to absorb the concentrated load by elastic compression and to transfer the residual load to the ground support slab 14 at the same time.

Then, concrete floor plates 12 and 12 are installed as shown in FIG. The concrete decks 12 and 12 form support jaws 122 and 122 so that the mortar filling spaces 121 and 121 have a predetermined depth h and a width w in the longitudinal direction at both ends thereof. The cushioning plates 18 and 18 manufactured in advance on the support jaw 122 and 122 may be fixedly installed. At this time, the concrete bottom plate (12, 12) is installed to be supported on the upper surface of the elastic pad (16, 16).

Next, as shown in FIG. 7, one end of the sleeve plate 20 is fixed to the one side cushion plates 18 and 18 with an anchor bolt 21, and the other end of the sleeve plate 20 is attached to the upper surface of the other cushion plate 18. Make contact for an interview. Therefore, the other end of the sleeve plate 20 becomes a free moving end.

Next, the elastic sealing material 24 is interposed in the interior of the closing mold 22, and then the finishing mold 22 is fixed to the other end of the sleeve plate 20 by fastening means 23 such as bolts, thereby allowing one side mortar. The charging space 121 is divided into two sides.

Then, mortar is cured by pouring it in the divided space around the finishing mold 22. Therefore, mortar layers 30a and 30b are formed on the joints of the concrete bottom plates 12 and 12 discontinuously and separated by the finishing mold 22 as shown in FIG. 1.

As described above, the construction method of the large-scale exhibition space floorboard expansion and contraction structure has the above-described structure to support the concentrated load on the elastic pads 16 and 16 at the point, thereby preventing cracking or breakage of the floor slab joint. In addition, the sleeve plate 20 slides freely in response to the expansion and contraction of the concrete bottom plates 12 and 12 according to the temperature change, corresponding to the change in the flow gap G.

Therefore, the joint spacing of the floor slab can be greatly increased, and thus, the actual area of the concrete slab 12 is reduced, thereby reducing the installation cost and improving workability. In addition, SOG has the advantage that large space can be used without ground subsidence.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

12: concrete deck
14: underground support slab
16: elastic pad
18: cushion plate
20: sleeve plate
22: closing mold
24: elastic sealing material

Claims (6)

An underground support slab 14 which is manufactured by in-situ casting or precast concrete, and which is located on the lower side of the joint formed between the gaps of the adjacent concrete slabs 12 and 12 and is supported by the rubble compaction layer 6; ;
Elastic pads 16 and 16 having elastic repulsive forces spaced apart from each other on an upper surface of the base support slab 14 to support the concrete bottom plates 12 and 12;
Made of cast-in-place or precast concrete, the support jaws 122 and 122 are formed on the elastic pads 16 and 16 to form mortar filling spaces having a predetermined depth (h) and a predetermined width (w) in the longitudinal direction at the ends thereof. Supported concrete slabs 12 and 12;
Cushion plates 18 and 18 fixed to both support jaws 122 and 122 through anchor bolts 19;
A sleeve plate 20 having one end fixed to one side cushion plate 18 and the other end thereof being in surface contact with the other side cushion plate 18;
A closing mold 22 having one end fixed to the other end of the sleeve plate 20 to divide the mortar filling space 121 into two sides;
An elastic sealing material 24 inserted into the closing mold 22; And
Large scale exhibition space floorboard stretch structure having a closing mold, characterized in that it comprises a mortar layer (30a, 30b) to pour cured in the divided space around the closing mold 22 to embed the sleeve plate (20). The method of claim 1,
The closing mold 22 is formed at the other end of the upper corrugated plate 221 having a corrugated shape, one side plate 222 vertically bent at one end of the upper corrugated plate 221, and the upper corrugated plate 221 to facilitate expansion and deformation. The other side plate 223 bent vertically, the flange 224 bent at right angles from the other side plate 223, the sealing member accommodating space portion 225 formed between the two side plates (222, 223), bonded to the one side plate 222 Large scale exhibition space floorboard stretch structure with a finishing mold, characterized in that it has a plurality of studs (226). The method of claim 1,
Sleeve plate 20 is a large-scale exhibition space floorboard stretch structure with a finishing mold, characterized in that the construction is made of fiber-reinforced plastic. The method of claim 1,
Cushion plate (18,18) is a large-scale exhibition space floorboard stretch structure with a finishing mold, characterized in that the construction is made of fiber-reinforced plastic. The method of claim 1,
Elastic sealing material 24 is a large scale exhibition space floorboard stretch structure with a closing mold, characterized in that made of rubber having a rectangular cross section. The underground support slab 14, which is manufactured by in-situ or precast concrete, is located on the lower side of the joint formed between the gaps of the adjacent concrete slabs 12 and 12 and is supported by the rubble compaction layer 6; Installing;
Installing elastic pads 16 and 16 spaced apart from each other on an upper surface of the base support slab 14 to support the concrete bottom plates 12 and 12;
It is made of cast-in-place or precast concrete, and the support jaw (122, 122) is formed to form a mortar filling space (121, 121) having a predetermined depth (h) and a predetermined width (w) in the longitudinal direction at the end of the support jaw ( Preparing the concrete bottom plates 12 and 12 having the cushion plates 18 and 18 installed on the elastic pads 16 and 16;
Fixing one end of the sleeve plate 20 to the one side support jaw 122 and making the other end of the sleeve plate 20 into surface contact with the upper surface of the other support jaw 122;
After the elastic sealing material 24 is interposed in the interior of the closing mold 22, the finishing mold 22 is fixed to the other end of the sleeve plate 20 to divide the mortar filling space 121 on both sides. Laying step;
A large scale exhibition space deck construction method with a finishing mold, characterized in that the construction through the step of burying the mortar in the divided space around the closing mold 22 to bury the sleeve plate (20).

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