KR20200132159A - Slim transfer mat structure and construction method with reverse drop panel - Google Patents

Abstract

The present invention relates to a slim transfer mat structure provided with a reverse drop panel and a construction method, in which the reverse drop panel is installed around a column having the greatest stress concentration to protrude from the upper part of the transfer mat when the transfer mat is constructed at a portion where different structure systems meet, thereby efficiently distributing stress around the column to reduce the thickness of the transfer mat and to have no loss in the height of the lower layer. A slim transfer mat structure provided with a reverse drop panel according to the present invention comprises: a plate-shaped transfer mat which is provided to transfer the weight of an upper structure having a wall structure to columns of an underground parking lot and is placed between the upper part of the column and the lower part of a wall of the upper structure to transfer the weight of the upper structure; a pit layer formed between the transfer mat and the upper structure; and a reverse drop panel installed on the upper part of the transfer mat at the position where the column is joined.

Description

Slim transfer mat structure and construction method with reverse drop panel}

In the present invention, when constructing a transfer mat at a site where different structural systems meet, by installing an inverse drop panel so that the stress concentration protrudes from the periphery of the column to the top of the transfer mat, the stress is efficiently distributed around the column. The present invention relates to a structure and construction method of a slim transfer mat equipped with an inverted drop panel that can reduce the thickness of the transfer mat and does not damage the lower floor height.

In general, apartment houses, such as apartments, are mostly wall-type structures whose bearing walls extend to the basement to form a pit in the lower part of the main building, and the passage or parking space of the basement window is mainly arranged between the main buildings.

However, urban environment improvement, which is one of the maintenance projects under the Urban and Residential Environment Improvement Act, which is implemented to improve the urban environment in areas that require efficient use of land, recovery of urban functions or revitalization of commercial districts as commercial and industrial areas. In the case of a project (province project), in many cases it is necessary to use the pit under the main building as a passage when planning a parking lot in consideration of the high floor area ratio and the spacing between urban areas. Therefore, in this case, a transfer floor between the long shoulders is required under the main body.

In addition, due to the plan of the upper shopping mall, the structure system of the residential-commercial complex building is inevitably different from the underground parking lot, and inevitably a transfer floor is required.

The transition layer is provided to smoothly transfer stress at a site where different structural systems meet. Conventionally, transfer beams (110, 120, tranfer girder) on the upper basement floor are used as a transfer layer to connect the wall 130 of the ground floor, which is a wall-type structure, and the lower pillar 101 of the basement layer, which is a ramen-like structure, as in Patent No. 10-1011402. Was mainly installed (Fig. 1).

However, when the upper main column and the underground parking lot do not coincide with the transfer beam, the diagonal wall beam 140 is inevitably formed as shown in FIG. 1. Therefore, there is a problem that the construction of the beam formwork is greatly deteriorated during the work of installing a formwork that is already cumbersome.

Accordingly, it is possible to consider a method of configuring the transfer layer of a thick slab structure as a transfer mat as shown in FIG. 2 so as to simplify the construction of the formwork and not be affected by whether the upper main column and the underground parking lot are matched.

At this time, the equipment standing (vertical) pipes descending from the upper main building must be able to be connected to the civil engineering pipes in the topi located at the upper part of the parking lot. However, unlike transfer beams that can penetrate facility piping, since the transfer mat is not legally allowed to embed facility piping inside, a separate PIT layer is required for facility piping on the top of the transfer mat.

However, in this case, if the height of the pit layer is low, it is difficult to install and dismantle the formwork for forming the pit layer, and it is difficult to move and work a worker for piping work. Conversely, if the height of the pit floor is increased, the total floor height of the underground parking lot is increased, causing an increase in construction costs and construction costs.

Such a pit layer needs to secure a ceiling height (H ₃ ) of about 1800 mm for the movement and work of the worker, and the transition mat needs a thickness of about t=1,500 mm based on the 20th floor height of the upper layer. And under the transition mat, a floor height of at least H ₂ =2900 mm should be secured.

Considering this, since the floor height of the underground parking lot is about H ₁ =4,400㎜, the construction cost is greatly increased and the construction cost is delayed due to the increase in the quantity of underground excavation and the quantity of column members, as well as the use of system support during construction due to the high floor height. Occurs.

In addition, if the thickness of the transition mat is 1,500 mm, cracks may occur due to the temperature difference between the inside and outside due to the heat of hydration, so it must be cut at a thickness of about 900 mm. At this time, in order to integrate the upper and lower concrete, there is a hassle of reinforcing the cut area with shear friction muscles.

In order to solve the above problems, the present invention is to provide a slim transfer mat structure and construction method provided with a reverse drop panel that is easy to install while minimizing the thickness of the transfer mat to reduce construction cost and time.

The present invention according to a preferred embodiment is for transmitting the load of the upper structure of the wall structure to the pillars of the underground parking lot, the plate-shaped transfer mat provided between the upper portion of the pillar and the lower portion of the wall of the upper structure to transfer the upper load; A pit layer formed between the transition mat and the upper structure; And a reverse drop panel installed on the transition mat at a position where the pillars are joined. It provides a slim transition mat structure provided with a reverse drop panel, characterized in that consisting of.

The present invention according to another preferred embodiment provides a slim-type transition mat structure with an inverse drop panel, characterized in that a first shear stiffener with an upper part embedded in the upper part of the inverse drop panel is provided inside the transition mat.

According to another preferred embodiment of the present invention, the first shear stiffener comprises a plurality of rows of an upper horizontal portion, an inclined portion bent downwardly obliquely at both ends of the horizontal portion, and a lower support portion bent in a horizontal direction at the ends of the inclined portion. It provides a slim transition mat structure with an inverted drop panel, characterized in that the shear reinforcement is provided in the longitudinal and transverse direction.

The present invention according to another preferred embodiment provides a slim transition mat structure provided with a reverse drop panel, characterized in that the upper reinforcement of the transfer mat is fixed to the inclined portion of the shear reinforcement bar.

The present invention according to another preferred embodiment is a slim type with a reverse drop panel, characterized in that a drop panel reinforcement in which a plurality of rows of upper reinforcement bars vertically bent downward at both ends are provided in the inside of the reverse drop panel. Provides a transition mat structure.

The present invention according to another preferred embodiment of the present invention is a second shear stiffener comprising a guide strip formed in a rectangular frame shape and a plurality of shear studs coupled to the lower portion of the guide strip on the transfer mat at the pillar position. It provides a slim transition mat structure equipped with a reverse drop panel, characterized in that it is mounted on the top of the reinforcing bar.

The present invention according to another preferred embodiment provides a slim transition mat structure with a reverse drop panel, characterized in that the reverse drop panel is formed of high-strength concrete than the transition mat.

The present invention according to another preferred embodiment is for constructing a slim-type transition mat structure provided with the reverse drop panel, (a) installing a formwork for constructing the pillar and the transition mat, and reinforcing reinforcing bars, respectively; (b) pouring concrete for forming the pillar and the transition mat; (c) installing a formwork for reverse drop panel construction on the upper part of the transfer mat at the position of the pillar; (d) pouring concrete of the reverse drop panel; And (e) forming a pit layer by constructing a wall of an upper structure on the transition mat. It provides a method of constructing a slim transition mat equipped with a reverse drop panel comprising a.

According to the present invention, there are the following effects.

First, when constructing a transfer mat at a site where different structural systems meet, a reverse drop panel is installed so that the stress concentration protrudes from the column around the column to the top of the transfer mat. It is possible to provide a slim transition mat structure and construction method provided with an inverted drop panel that can reduce the thickness of the mat and does not damage the lower floor height. Accordingly, it is possible to reduce the amount of excavation under the ground, and since the use of system support is unnecessary due to the reduction in floor height in the underground parking lot, construction cost can be reduced.

Second, since the transfer mat can be constructed in one pour without vertical breaking, it is possible not only to save air but also to omit the installation of shear friction reinforcing bars at the breaking area.

Third, since the reverse drop panel is installed only on the top of the column, the operator can freely move and work from the pit floor to the space between the reverse drop panels.

Fourth, since there is no part protruding from the lower part of the transfer mat, installation of the formwork and support is very simple, and thus the workability is excellent.

1 is a diagram showing a transition layer using a conventional transition beam.
2 is a diagram showing a transition layer using a conventional transition mat.
3 is a side cross-sectional view showing a structure of a slim transition mat equipped with an inverse drop panel of the present invention.
Figure 4 is a perspective view showing the structure of a slim transition mat equipped with the present invention reverse drop panel.
5 is a side cross-sectional view showing a state in which a first shear stiffener is disposed.
6 is a perspective view showing an embodiment of a first shear stiffener.
7 is a view showing an embodiment of a shear reinforcement bar constituting a first shear reinforcement member.
8 is a perspective view showing an embodiment of a drop panel reinforcement.
9 is a side cross-sectional view showing a state in which a drop panel reinforcement is disposed.
Fig. 10 is a perspective view showing an embodiment of a second shear stiffener.
Fig. 11 is a side cross-sectional view showing a state in which a second shear stiffener is disposed.
12 is a view showing a step-by-step process for a method of constructing a slim transition mat equipped with a reverse drop panel according to the present invention.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

3 is a side cross-sectional view showing a structure of a slim-type transition mat equipped with an inverse drop panel of the present invention, and FIG. 4 is a perspective view illustrating a structure of a slim-type transition mat having an inverse-drop panel of the present invention.

As shown in FIGS. 3 and 4, the slim transition mat structure provided with the reverse drop panel of the present invention is for transferring the load of the upper structure, which is a wall-type structure, to the pillar 1 of the underground parking lot, and the pillar 1 A plate-shaped transfer mat 3 provided between the upper part and the lower part of the wall 2 of the upper structure to transfer the upper load; A pit layer 4 formed between the transition mat 3 and the upper structure; And a reverse drop panel 5 installed on the transition mat 3 at the position where the pillar 1 is joined. It characterized in that it consists of.

The present invention is a transfer layer that is installed to smoothly transfer stress at a site where different structural systems meet. When constructing a transfer mat, the thickness of the transfer mat 3 is minimized to reduce construction cost and construction time. It is to provide a slim transition mat structure and a construction method provided with a reverse drop panel that is easy to construct.

In particular, the present invention relates to a slim transition mat structure using a reverse drop panel used in an underground parking lot.

The upper structure located on the upper part of the transition layer is composed of a wall-type structure, and the lower structure is composed of an underground parking lot with a ramen structure including a column (1).

A transition layer composed of a transition mat 3, a pit layer 4, and a reverse drop panel 5 is provided between the upper structure and the lower structure.

The transition mat 3 is a plate-shaped slab having a predetermined thickness, and is provided between the upper part of the pillar 1 of the underground parking lot and the lower part of the wall 2 of the upper structure to transmit the upper load to the lower part.

The pit layer 4 is a space formed between the transition mat 3 and the upper structure, and is a separate space for piping various facilities.

The reverse drop panel 5 is installed on the upper part of the transition mat 3 where the pillars 1 of the underground parking lot are joined.

Accordingly, a drop panel is installed with a thicker thickness of the transition mat (3) only around the pillar (1) with the greatest stress concentration in the transition structure, but the reverse drop panel (5) so that the drop panel protrudes from the top of the transition mat (3) By constituting with, it is possible to efficiently distribute the stress around the pillar (1) while preventing damage to the lower floor height.

Since the installation of the reverse drop panel 5 can reduce the thickness of the transition mat 3 by about 600 mm, as a result, the thickness t'of the transition mat 3 can be reduced to about 900 mm or less.

Therefore, it is possible to lower the floor height (H ₁ ') of the underground parking lot to 3,900 mm while maintaining the floor height (H ₂ ) under the main building at 2900 mm.

Therefore, it is possible to reduce the amount of excavation in the ground, and the use of system support is unnecessary due to the reduction in the height of the underground parking lot. In addition, since the transfer mat 3 can be poured once without breaking vertically, it is possible to save air and eliminate the work of installing shear friction reinforcing bars in the cut areas.

In addition, since the reverse drop panel 5 is installed only on the pillar 1, the operator can freely move and work from the pit layer 4 to the space between the reverse drop panels 5.

That is, in spite of the provision of the reverse drop panel 5, there is no obstacle to the operator's work, and there is no damage to the floor height.

The size of the reverse drop panel 5 is configured to be greater than or equal to the size of the dangerous cross section based on the outer surface of the column 1.

Existing drop panels are formed under the slab and protrude from the bottom of the slab, so the shape of the lower formwork is complicated and the length of the support has to be changed. On the other hand, in the present invention, since there is no part protruding from the lower part of the transition mat 3, installation of a formwork and a support is very simple, and thus workability is excellent.

5 is a side cross-sectional view showing a state in which the first shear stiffener is disposed.

As shown in FIG. 5, a first shear stiffener 6 may be provided inside the transition mat 3 and having an upper portion buried above the reverse drop panel 5.

The first shear stiffener 6 supports a shear force acting on the transition mat 3 and the reverse drop panel 5 above the column 1.

The reverse drop panel 5 is advantageously placed separately from the transfer mat 3 for construction. At this time, the first shear stiffener 6 may serve as a shear friction reinforcing bar that integrates the reverse drop panel 5 and the transition mat 3. Therefore, it is possible to omit a separate shear friction reinforcing bar.

In addition, when the concrete of the transfer mat (3) and the reverse drop panel (5) is separately poured, it is difficult to accurately determine the position of the column (1) from the top of the transfer mat (3), so the position of the reverse drop panel (5) is set. This can be difficult. At this time, since the first shear stiffener 6 protrudes to the upper portion of the transition mat 3, the reverse drop panel 5 can be installed at an accurate position.

Fig. 6 is a perspective view showing an embodiment of the first shear stiffener, and Fig. 7 is a view showing an embodiment of the shear reinforcement bar constituting the first shear stiffener.

6 and 7, the first shear stiffener 6 includes an upper horizontal portion 61, an inclined portion 62 that is bent downwardly at both ends of the horizontal portion 61, and the inclined A plurality of rows of shear reinforcement bars 60 composed of a lower support part 63 that is bent in a horizontal direction at the end of the part 62 may be provided in a vertical and horizontal direction.

In general, the fracture surface by punching shear at the top of the column 1 occurs at an angle of approximately 45° upward and outward.

Therefore, the shear reinforcement bar 60 can be formed to be inclined downward at an angle of approximately 45° to the outside so as to be reinforced in a direction orthogonal to the expected fracture surface.

A lower support part 63 bent in a horizontal direction may be formed at the end of the inclined part 62 so that the first shear stiffener 6 can be stably mounted on the lower reinforcing bar 31 of the transfer mat 3. have.

The horizontal portion 61 positioned above the shear reinforcement 60 is spaced apart from the inclined portions 62 on both sides so that the horizontal portion 61 can roughly penetrate the center of the predicted fracture surface. In addition, the horizontal portion 61 serves as an upper reinforcing bar of the reverse drop panel 5 itself.

As shown in FIG. 5 and the like, the upper reinforcing bar 32 of the transfer mat 3 may be fixed to the inclined portion 62 of the shear reinforcing bar 60.

On the transfer mat 3, the lower reinforcing bar 31 and the upper reinforcing bar 32 are vertically spaced apart. However, since the upper reinforcing bar 32 is placed at a quite high position from the floor, a support reinforcing bar (Uma reinforcing bar) is required at the top of the lower reinforcing bar 31 after reinforcing the lower reinforcing bar 31 to separate the upper reinforcing bar 32 from the floor. .

In the present invention, since the shear stiffeners 60 constituting the first shear stiffener 6 are spaced apart from each other at regular intervals, the supporting reinforcement can be omitted by supporting the upper reinforcing bar 32 with the shear stiffener 60.

That is, the upper reinforcing bar 32 of the transfer mat 3 is mounted on the inclined portion 62 of the shear reinforcing bar 60, and the upper reinforcing bar 32 is bound to the inclined part 62 with a binding line, etc. I can.

Fig. 8 is a perspective view showing an embodiment of the drop panel reinforcement, and Fig. 9 is a side cross-sectional view showing a state in which the drop panel reinforcement is disposed.

As shown in FIGS. 8 and 9, the reverse drop panel 5 may be provided with a drop panel reinforcement 7 in which a plurality of rows of upper reinforcement bars vertically bent downward at both ends are coupled in a longitudinal and transverse direction.

When the strength is insufficient only by the shear reinforcing bar 60 of the first shear reinforcement 6, a drop panel reinforcement 7 may be provided inside the reverse drop panel 5 to reinforce the strength.

The drop panel reinforcement 7 may be formed in a cap shape by vertically bending each end of a plurality of rows of upper reinforcement bars intersecting in a vertical and horizontal direction (FIG. 8).

That is, the upper reinforcement muscle may be configured in a U shape in which both ends are bent downward.

Accordingly, the drop panel reinforcement 7 can be easily installed by simply mounting on the upper part of the transition mat 3.

In addition, the modularized and pre-assembled drop panel reinforcement 7 is simply placed on the transition mat 3, so the construction is very simple and quick.

Alternatively, the drop panel reinforcement 7 may be mounted on the horizontal portion 61 of the first shear reinforcement 6.

Fig. 10 is a perspective view showing an embodiment of a second shear stiffener, and Fig. 11 is a side cross-sectional view showing a state in which the second shear stiffener is disposed.

10 and 11, the transition mat 3 at the position of the pillar 1 includes a guide strip 81 formed in a rectangular frame shape, and a plurality of guide strips coupled to the lower portion of the guide strip 81. The second shear stiffener 8 composed of the shear stud 82 may be configured to be mounted on the upper reinforcing bar 32 of the transition mat 3.

The reverse drop panel 5 may be constructed in the same size and shape by standardizing the size of the formwork for convenience in construction and material management.

However, if the amount of shear force around the column 1 is large, it may be difficult to support it with only the reverse drop panel 5 having a standardized size. In this case, by installing the second shear stiffener 8 inside the transition mat 3 without increasing the size of the reverse drop panel 5, it is possible to support the shear force.

The second shear stiffener 8 includes a guide strip 81 configured in a rectangular frame shape in plan view and a plurality of shear studs 82 coupled to the lower portion of the guide strip 81.

The guide strip 81 may be formed using a flat bar or the like.

The shear stud 82 may be welded to the lower portion of the guide strip 81.

The second shear stiffener 8 is installed inside the transition mat 3 above the pillar 1.

The stud rails used in the existing flat plate structure are mounted on the lower reinforcing bar 31 of the slab in a state in which shear studs are coupled to the upper guide strip.

However, if the stud rail is simply mounted on the upper part of the lower reinforcing bar 31, there is a possibility of moving the position during concrete pouring, so a separate fixing is required.

On the other hand, the second shear stiffener 8 of the present invention is provided with a shear stud 82 at the lower portion of the guide strip 81 so that the guide strip 81 is mounted on the upper reinforcing bar 32 of the transition mat 3 , Each shear stud 82 is caught between the neighboring upper reinforcing bars 32. Accordingly, there is no fear of moving the position of the second shear stiffener 8 when the transfer mat 3 is poured into concrete.

That is, the above-described first shear stiffener 6 is mounted on the lower reinforcing bar 31 of the transfer mat 3 to stand alone, and the upper reinforcing bar 32 of the transfer mat 3 is the first shear stiffener 6 It is mounted on, the second shear reinforcement (8) is mounted on the upper reinforcement (32). Therefore, stable mounting of each member is possible, and construction is very simple.

The reverse drop panel 5 may be formed of high-strength concrete than the transition mat 3.

The load of the transfer mat 3 is transmitted to the column 1 through the reverse drop panel 5 so that the stress is mainly concentrated in the reverse drop panel 5. However, in the present invention, since the transfer mat 3 is first constructed and the reverse drop panel 5 is separated for post-construction, it is possible to construct the transfer mat 3 and the reverse drop panel 5 with concrete of different strengths.

Therefore, the transition mat 3 uses a general strength concrete of about 27 MPa, and the reverse drop panel 5 uses a high strength concrete of about 40 MPa, thereby enabling efficient and economical design.

12 is a diagram showing a step-by-step process for a method of constructing a slim transition mat equipped with an inverse drop panel according to the present invention.

The method of constructing the slim-type transition mat provided with the inverse drop panel of the present invention is to construct the slim-type transition mat structure provided with the inverse drop panel of the present invention described above with reference to FIGS. 3 to 11.

In the method of constructing a slim-type transition mat equipped with an inverted drop panel of the present invention, (a) the pillar (1) and the transition mat (3) are installed in the formwork (12, 33) for construction, while reinforcing bars (11, 31, respectively) Step 32) is carried out (Fig. 12 (a)).

Specifically, step (a) may proceed in the order of reinforcing the column reinforcement (11) → installing the column formwork (12) → installing the transfer mat formwork (33) → reinforcing the transfer mat reinforcement (31, 32).

After reinforcing the lower reinforcing bar 31 of the transfer mat 3, the first shear reinforcement 6 is installed on the lower reinforcing bar 31 of the column 1 so that the upper part protrudes above the upper surface of the transfer mat 3 I can.

The upper reinforcing bar 32 of the transfer mat 3 may be installed to be mounted on the first shear stiffener 6. Accordingly, the reinforcement of the upper reinforcing bar 32 is possible without a separate support reinforcing bar.

When it is difficult to support the shear force only with the reverse drop panel 5 and the first shear stiffener 6, the second shear stiffener 8 is replaced with the first shear stiffener 6 after the upper reinforcing bar 32 of the transfer mat 3 is laid. It can be mounted and installed on the upper reinforcing bar 32 outside.

The second shear stiffener 8 may include a guide strip 81 formed in a rectangular frame shape and a plurality of shear studs 82 coupled to a lower portion of the guide strip 81.

And (b) pouring concrete (C ₁ , C ₂ ) for forming the pillar (1) and the transition mat (3) (Fig. 12 (b)).

The concrete placing step includes a process of demolding the formwork after curing the concrete.

In other words, concrete (C ₁ , C ₂ ) is poured into the molds 12 and 33 of the column 1 and the transfer mat 3 to be cured, and the molds 12 and 33 are demolded.

Concrete (C ₁ , C ₂ ) for forming the pillar (1) and the transition mat (3) can be poured at the same time, and when concrete of different strengths is applied to the pillar (1) and the transition mat (3), It is also possible to pour separately from each other.

In the present invention, since the reverse drop panel 5 is provided so that the total thickness of the transition mat 3 can be reduced to 1m or less, it is possible to pour one time without breaking the concrete (C ₂ ) of the transition mat 3 .

Next, (c) a formwork 51 for construction of the reverse drop panel 5 is installed on the top of the transfer mat 3 at the position of the column 1 (Fig. 12(c)).

When the concrete (C ₂ ) of the transfer mat 3 is cured to a certain strength or more, a form 51 for construction of the reverse drop panel 5 is installed on the top of the transfer mat 3.

At this time, the transfer mat 3 can be used as a work space.

The formwork 51 for the reverse drop panel 5 is simply mounted on the top of the transition mat 3, so construction is very convenient.

The upper and lower portions of the formwork 51 of the reverse drop panel 5 are opened, and only the sides need only be closed. Therefore, it is possible to simplify the installation work of the formwork 51 by modularizing it into four standardized side panels.

When the strength is insufficient only by the shear reinforcement 60 of the first shear reinforcement 6, the drop panel reinforcement 7 may be installed inside the reverse drop panel 5 to reinforce it.

Thereafter, (d) the concrete (C ₃ ) of the reverse drop panel 5 is poured (FIG. 12(d)).

In this case, concrete (C ₃ ) is poured into the open portion of the upper part of the formwork 51 of the reverse drop panel 5 to cure, and the formwork 51 is then dismantled.

In this way, when the transfer mat 3 and the reverse drop panel 5 are separately constructed, workability is improved.

Finally, (e) the pit layer 4 is formed by constructing the wall 2 of the upper structure on the upper part of the transition mat 3 (FIG. 12(e)).

The wall 2 may be installed across the reverse drop panel 5.

1: column 11: rebar
12: formwork 2: wall
3: transfer mat 31: lower reinforcement
32: upper reinforcing bar 33: formwork
4: Pit layer 5: Reverse drop panel
51: formwork 6: first shear stiffener
60: shear reinforcement 61: horizontal portion
62: inclined portion 63: lower support portion
7: drop panel reinforcement 8: second shear reinforcement
81: guide strip 82: shear stud
C ₁ , C ₂ , C ₃ : Concrete H ₁ : Floor height in underground parking lot
H ₂ : Height below the main building H ₃ : Height of the pit floor
t: thickness of the transition mat

Claims (8)

It is to transmit the load of the upper structure, which is a wall structure, to the pillar (1) of the underground parking lot,
A plate-shaped transfer mat (3) provided between the upper part of the pillar (1) and the lower part of the wall (2) of the upper structure to transfer the upper load;
A pit layer 4 formed between the transition mat 3 and the upper structure; And
A reverse drop panel (5) installed on the transition mat (3) at a position where the pillar (1) is joined; Slim type transition mat structure equipped with a reverse drop panel, characterized in that consisting of.
In claim 1,
A slim transition mat structure with an inverted drop panel, characterized in that a first shear stiffener (6) having an upper portion embedded in the upper portion of the inverse drop panel (5) is provided inside the transition mat (3).
In paragraph 2,
The first shear stiffener 6 is bent in a horizontal direction at an upper horizontal portion 61, an inclined portion 62 bent downwardly obliquely at both ends of the horizontal portion 61, and an end portion of the inclined portion 62 A slim transition mat structure with an inverted drop panel, characterized in that a plurality of rows of shear reinforcement bars 60 composed of a lower support part 63 are formed in a vertical and horizontal direction.
In paragraph 3,
The upper reinforcing bar (32) of the transfer mat (3) is fixed to the inclined portion (62) of the shear reinforcing bar (60).
In claim 1,
A slim transition mat structure with a reverse drop panel, characterized in that a drop panel stiffener 7 is provided in which a plurality of rows of upper reinforcing bars vertically bent downward at both ends are provided inside the reverse drop panel 5 .
In paragraph 3,
A second shear consisting of a guide strip 81 formed in a rectangular frame shape and a plurality of shear studs 82 coupled to a lower portion of the guide strip 81 on the transition mat 3 at the position of the pillar 1 A slim transition mat structure with a reverse drop panel, characterized in that the reinforcing material 8 is mounted on the upper reinforcing bar 32 of the transition mat 3.
In claim 1,
The reverse drop panel (5) is a slim transition mat structure provided with a reverse drop panel, characterized in that formed of high-strength concrete than the transfer mat (3).
It is for constructing a slim transition mat structure equipped with a reverse drop panel according to any one of claims 1 to 7,
(a) installing a formwork (12, 33) for the construction of the pillar (1) and the transfer mat (3), while reinforcing reinforcing bars (11, 31, 32), respectively;
(b) pouring concrete (C ₁ , C ₂ ) for forming the pillar (1) and the transition mat (3);
(c) installing a formwork 51 for construction of the reverse drop panel 5 on the top of the transfer mat 3 at the position of the column 1;
(d) pouring concrete (C ₃ ) of the reverse drop panel 5; And
(e) forming a pit layer (4) by constructing a wall (2) of an upper structure on an upper portion of the transition mat (3); Construction method of a slim transition mat provided with a reverse drop panel comprising a.

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