JP2007239449A - Heat insulation structure and precast concrete body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a heat insulation structure which achieves application thereof to reinforcements of building constructions adjacent thereto, via the flexibility there in the construction field. <P>SOLUTION: A heat insulator 7 of the heat insulation structure connected to both the building constructions is formed of at least three separate parts. Two of the parts include a leg portion 8 extending over the entire length L of the heat insulation structure 1 on a lower side thereof, and a reinforcing portion 9 arranged on a vertically upper side of the leg portion 8, having reinforcements 13, and being short in horizontal length than the leg portion 8. The remaining one of the separate parts includes at least one supplementary portion 10, 11 which horizontally adjoins the reinforcing portion, and is positioned to a vertically upper portion of the leg portion. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention is a thermal insulation structure between two building structures (eg, a building ceiling or building wall and a balcony protruding therefrom), one of which protrudes from the other, at least the insulator, It consists of a reinforcing bar which penetrates the insulator and is connected to both building structures.

  In particular, if the building ceiling is not made of a single ceiling panel but has a framed structure of reinforced concrete beams, often in the connection area of this beam to the heat insulating structure Problems arise in positioning the reinforcing bars arranged corresponding to the body. This is because these reinforcing bars may interfere with the reinforcing bars of the reinforced concrete beam. In the conventional system, the heat insulation structures are manufactured and assembled with each other with a predetermined grid of reinforcement bars and thus with a standardized spacing of the individual reinforcement bars, so that they interfere in the connection area to the reinforced concrete beam. It is obvious that it is easier because the reinforcing bars of reinforced concrete beams have different lattice structures, ie different spacings.

  In view of the above situation, an object of the present invention is to provide a heat insulating structure that enables adaptation of an adjacent building structure to a reinforcing bar through the variability of the structure at a construction site.

  A heat insulating structure between two building structures (for example, a building ceiling or building wall and a balcony protruding therefrom), one of which protrudes from the other, comprising at least an insulator and the insulator In order to solve the above-mentioned problem, the insulator is composed of at least three separate parts in the present invention in order to solve the above-mentioned problem in the reinforcing bars that penetrate and are connected to both building structures. Two of the parts are a leg part extending below the entire length of the heat insulating structure, and a reinforcing part which is disposed above the leg part in the vertical direction and has the reinforcing bar, The reinforcing portion has a horizontal length shorter than the leg portion, and at least one of the portions is aligned with the reinforcing portion in the horizontal direction and the vertical direction in the vertical direction. leg Which is the upward positionable complement portion.

  This configuration has the advantage that the legs can be positioned as space holders in the connection region to the reinforced concrete beam or other building structure with limited connection. This is because the legs do not have reinforcing bars protruding into the building-building structure that may interfere. The upper region of the leg that functions as a space holder is provided on the one hand for the reinforcing part and on the other hand for at least the complementary part. The reinforcing part and the single or plural complementary parts have a total length corresponding to the length of the leg part. Accordingly, the reinforcement is configured to be shorter than the legs, and the reinforcement is a reinforcement that is generally a reinforcing bar in each of the connecting building structures that may interfere with each other, i.e., particularly adjacent reinforced concrete beams. The entire length of the leg is moved until it is inserted into the rebar. The reinforcing part is arranged on the same vertical plane as the leg part. Furthermore, in the same vertical plane, the length that is still insufficient with respect to the length of the leg portion on one or both sides of the reinforcing portion is supplemented by adding one or more complement portions. The leg portion, the reinforcement portion, and the complement or complements together form an insulator. The length extending in the longitudinal direction of the insulator corresponds to the length extending in the longitudinal direction of the leg portion, and the height of the insulator corresponds to the total height of the leg portion and the reinforcing portion or the complementary portion.

  Adopting an insulator modular structure (divided structure), cutting and adapting work to the insulator body manually at the construction site can be avoided. These cutting and adapting operations have been required when applying conventional conventional thermal insulation structures to a given reinforcing bar grid.

  Insulation structures with modular insulation are used in the above-mentioned connection areas where there is a risk of interference, whereas other areas with normal insulation structures use the specified reinforcement bars Has been. In this case, the lengths of the two heat insulating structures are usually defined in the design drawing and cannot be adjusted at the construction site.

  In general, there is only one area with a reinforcing bar, which is a reinforcing bar, which is likely to interfere, i.e., the reinforcing part and the building structure which does not have a reinforcing bar or at least has a risk of interference. A precast concrete body comprising a precast panel having a provided insulator by using a modular insulator comprising a leg portion and one or a plurality of complementary portions that do not have a reinforcing bar, That is, it can be used especially for reinforced concrete beam ceilings. For this purpose, it is preferable to provide one leg of the modular insulator described above only in the precast panel in the connection area where there is a possibility of interference. Thereby, exact positioning of a reinforcement part and a single or several complement part can be performed on a construction site. Conventional heat insulation structures of the conventional structure that are in the same row with respect to the directly connected legs can already be connected to the precast panel at the precast manufacturing plant. This is because the rebar of the normal heat insulating structure extends into a region where there is no possibility of interference, and adjustment work at the construction site is not necessary. Accordingly, the precast concrete body according to the present invention comprises a precast panel having an added insulator, and the added insulator comprises the leg portion of the heat insulating structure according to the present invention, and the added insulator is The heat insulation structure by this invention is constructed | assembled with the said reinforcement part and the said complement part.

  As long as the leg has a predetermined length, the above-mentioned space holder function is created in the leg, so the leg may be of any leg height, but the leg is already as described above, When already providing a space holder function for the legs in a precast manufacturing plant, it is particularly advantageous if the legs have a height approximately corresponding to the height of the precast panel. In this case, the precast panel serves as part of a building structure, in particular a balcony plate, that protrudes against the building and can be connected to a heat insulating structure. Thereby, a leg part does not disturb the manufacturing process of a precast panel. In this case, the legs can function as a mold that is lost in the production of the precast panel in the normal form. In addition, the height of the legs does not detract from the minimum height available for the reinforcement bars in the reinforcement area of the insulator that will be placed above the legs. .

  The leg portion may have a vertical height substantially corresponding to the compression region on the lower side of the heat insulating structure in the assembled state. This dimension is considered by the situation. That is, this dimension is sufficient when the reinforcing part does not normally have a compression holding part, the reinforcing bar does not extend downward to the compression area, and this compression area can be left to the leg part. .

  Compared to the overall height of the insulation structure in the vertical direction, the legs are approximately perpendicular to the total height of the insulation structure between 1/4 and 1/2, in particular between 1/3 and 1/2. It is advantageous to have a height in the direction. If these are the usual size of the insulation structure (height between approximately 16 cm and 25 cm), the vertical height of the legs is between approximately 5 cm and 10 cm, in particular approximately 8 cm.

  In the improvement of the connection of the leg part, the reinforcing part and the complementary part to the heat insulating structure, or in the improvement of the connection of the reinforcing part to the single or plural complementary parts, the leg part, the reinforcing part and the complementary part, Forming one convex portion extending over the height on each end face and a concave portion extending over the entire height corresponding to the one convex portion on the other opposite end face. A geometrically engaged connection between the body and the tooth shape results. This tooth-shaped shape connection prevents the formation of a seam through the insulator and allows the teeth to provide a better and more stable connection with the adjacent insulator.

  The particular advantage of the thermal insulation structure of the present invention is that the thermal insulation structure of the present invention with reinforcing bars, which in any case is different from the conventional thermal insulation structure, is used for a completely different type of load. Can be obtained. The conventional heat insulation structure, which is a conventional product, is composed of an upper tensile reinforcement bar, a lower compression reinforcement bar, and a shear bar extending obliquely downward from above in a substantially intermediate region. For this reason, these ordinary thermal insulation structures are not necessarily designed to withstand load loads and moment loads caused by earthquakes. The following advantages can be obtained by attaching another reinforcing bar designed for seismic load to these heat insulating structures. For example, the reinforcement part of the heat insulation structure of this invention has the shearing member provided especially for the seismic load as a suitable embodiment, especially a shear reinforcement. The shear bar is similar to the conventional shear bar of a normally insulated structure, and extends diagonally through the insulator and at the exit region of the shear bar exiting the insulator, the shear bar is substantially perpendicular. It is curved to protrude with respect to the insulator. Particularly preferred is the use of shear bars that extend along a horizontal plane, in particular approximately in the region above the reinforcement bars. In that case, it is good to provide two each of the shear muscles extended in mirror symmetry mutually. These shear bars must be able to withstand shear forces in both horizontal directions along the insulator plane, i.e. a force direction that does not matter for the normal static loads of these types of insulation structures. In one preferred embodiment, the shear bar extends over a region that is approximately slightly shorter than the width of the reinforcement, wherein the shear bar is approximately at a 45 ° angular range with respect to the insulator plane. And extends diagonally through the insulator.

  Alongside this, of course, the insulator reinforcement is advantageously provided with shear bars extending in a vertical plane in a general manner. In so doing, the shear bars may extend substantially over a height slightly less than the height of the reinforcement.

  Yet another important load caused by an earthquake is a tipping moment about the horizontal insulator longitudinal axis. This overturning moment is caused, for example, when the protruding balcony plate does not rotate downward due to the weight of the balcony plate, as in normal seismic loads, but is applied upward due to the rotational moment acting in the opposite direction. ing. In order to accept such a moment, in one preferred embodiment, the reinforcement has a tension member, in particular a tension bar, provided in the lower region for seismic loads. The tensile force member protrudes in a horizontal direction with respect to the reinforcing portion, particularly at a right angle with respect to the insulator. These tension members likewise serve to receive pure horizontal loads in a direction perpendicular to the insulator plane. These pure horizontal loads, i.e., approximately the acceleration of the different strengths of the two adjacent building structures, cause the two building structures to be separated from each other.

  The following additional features relating to the use of the thermal insulation structure of the present invention in conjunction with a precast concrete body provide the following advantages: The reinforcing bars of the heat insulating structure extend substantially in the region above the precast panel on the side of the heat insulating structure facing the precast panel. As a result, the reinforcing bars to be incorporated together with the reinforcing part of the insulator are not already inserted into the precast panel in the precast manufacturing factory, but are actually connected to each connection state at the construction site for the first time. It can be added accurately.

  As already mentioned, it is further proposed to combine the second type of conventional ordinary thermal insulation structure with the precast concrete body of the present invention. Unlike the present invention, these heat insulation structures are made of a non-modular insulator having an integrated reinforcing member. Reinforcing members integrated into these thermal insulation structures extend at least partially through the precast panel, a compression receiver connected to the precast panel, a tensile bar extending horizontally in the upper region of the precast panel, and It consists of shear muscles. Therefore, the heat insulation structure of the present invention having the legs functioning as the space holder and the conventional heat insulation structure of the second type are joined to the precast panel for manufacturing the precast concrete body. In this case, the second type of heat insulating structure is composed of a conventional ordinary heat insulating structure that serves to absorb strong tensile, compressive and shear forces.

Other components and advantages of the present invention will be described below based on the illustrated embodiments.
In FIG. 1, the heat insulation structure 1 of this invention is joined between the two normal heat insulation structures 2 which are conventional products. In order to clarify the difference between the normal heat insulating structure 2 and the heat insulating structure 1 of the present invention, first, the structure of the normal heat insulating structure 2 will be described. The normal heat insulating structure 2 includes an insulator 3 and reinforcing bars. The reinforcing bar extends through the insulator from the upper side to the lower side, the pulling bar 4 that extends in the horizontal direction on the upper side, the compression receiving part 5 that is arranged in the same manner as the lower side insulator, and the insulator. And a shear line 6 curved in the horizontal direction outside the insulator. As apparent from FIG. 1, these reinforcing bars are provided corresponding to a predetermined lattice structure adapted to each load. Such an insulator of the normal heat insulating structure 2 is usually divided in the horizontal direction in order to facilitate positioning of the reinforcing bar within the region of the reinforcing bar.

  The structure of the heat insulating structure 1 of the present invention, which is different from the normal heat insulating structure 2, is apparent from FIGS. The heat insulating structure 1 has a modular insulator 7. The insulator 7 includes a lower insulator leg 8 extending over the entire length L of the heat insulating structure 1, a reinforcing part 9 that is an insulator disposed above the leg 8, and a leg similarly. 8 is composed of two complementary portions 10 and 11 which are insulators arranged above 8. The reinforcing portion 9 has a length M shorter than the length L of the leg portion 8, and the complementary portions 10 and 11 also have a length N or P shorter than the length L of the leg portion 8. Yes. The total length of the length M of the reinforcing portion 9, the length N of the complementary portion 10, and the length P of the complementary portion 11 corresponds to the length L of the leg portion 8.

  The leg 8 occupies a predetermined position between the normal heat insulation structure 2 on the left side and the normal heat insulation structure 2 on the right side in the drawing, whereas the leg portion 8 includes the reinforcement portion 9 and the complementary portions 10 and 11. The position is variable. That is, the complementary portions 10 and 11 do not have reinforcing bars in the same manner as the leg portions 8 and can be positioned without considering any building structure to be connected. However, the reinforcing portion 9 has a reinforcing bar 13. The reinforcing bars 13 include a lower tensile bar 12, lateral shear bars 14, 15, 16 extending in a horizontal plane and a vertical shear bar 16 extending in a vertical plane. The reinforcing bar 13 protrudes in the direction of the building structure in contact with the reinforcing portion 9 with respect to the reinforcing portion 9. The protrusion of the reinforcing bar 13 is not a problem at the time of installation in the region of the protruding building structure B, but on the other side, in this region at the connection to another building structure, in particular the building roof A. There is a problem that the reinforcing bars 17 extend almost to the edge region of the building roof A, and the reinforcing bars 13 of the reinforcing portion 9 are likely to come into contact with the reinforcing bars 17 of the building roof A. In order to avoid this contact (interference), the reinforcing part 9 has longitudinal arrows C and C of the heat insulating structure 1 such that the reinforcing bars 13 of the reinforcing part 9 are inserted between the reinforcing bars 17 of the building roof A. Moved along. In this case, the reinforcing portion 9 is inserted into the building roof A, which is a building structure, so as to be in the same row as the leg portion 8, and further, the complementary portions 10 and 11 can be adjacent to the heat insulating structure 2 that can be adjacent thereto. It is added to the left or right or both to fill the remaining gap.

  2 to 6, the complementary portions 10 and 11 are disposed on both sides of the reinforcing portion 9. On the other hand, in FIGS. 7 and 8, the complementary portions 10 and 11 are left there with respect to the right heat insulating structure 2 after the reinforcing portion 9 directly contacts the left heat insulating structure 2. In order to fill a large gap, the reinforcing portion 9 is disposed only on one side.

  It is possible to use a plurality of forms that can obtain the full length L corresponding to the leg portion 8 together with the reinforcing portion 9 as the complementary portion. In many cases, two complementary parts of the same size are used, and these two complementary parts are placed on the left or right side of the reinforcing part, or on the left side of the reinforcing part with one complementary part and on the right side the other complementary part. In the same row, in the insulator plane, they are arranged above the legs. With these configurations, the reinforcing portion 9 can be arranged at three different layout positions.

  2 and 4, it can be understood that the leg portion 8 has a height corresponding to the height of the precast panel B '. The precast panel B 'constitutes a building structure B (the height of the precast panel B' is indicated by a dotted line 18 in FIGS. 2 and 4). However, it is of course possible to adopt a form in which the leg 8 has a height different from that of the precast panel B 'or a form in which the precast panel B' is not used at all.

  In summary, the advantage of the present invention is that it provides the following thermal insulation structure. That is, the modular structure of the heat insulating structure enables the non-interfering connection of the heat insulating structure to the connecting reinforcing bars without considering the manufacturability in the assembly process of the precast manufacturing factory or the construction site. To that end, it has a lower leg provided as a space holder for two adjacent, usually normal thermal insulation structures, a shorter length than the leg, and sets a convenient non-interfering position For this purpose, reinforcing parts are used which can be moved over the entire range of the legs. The gap left between the reinforcing portion and the adjacent heat insulating structure is filled with the complementary portion, and the total length of the reinforcing portion and the used complementary portion corresponds to the length of the leg portion. It will be.

The perspective view of the heat insulation structure of this invention joined to the normal heat insulation structure The front view in one embodiment of the heat insulation structure of this invention Plan view of the heat insulation structure of FIG. The perspective view of the heat insulation structure of FIG. Plan view of reinforcement Front view of reinforcement The front view in another embodiment of the heat insulation structure of this invention The top view of the heat insulation structure of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Thermal insulation structure 7 Insulator 8 Leg part 9 Reinforcement part 10,11 Supplement part 12 Tensile muscle 13 Reinforcement reinforcement 14 Shear reinforcement (lateral shear reinforcement)
15 Shear muscle (lateral shear muscle)
16 Shear (longitudinal shear)
A, B Building structure

Claims (16)

A heat insulating structure between two building structures, one of which protrudes from the other, comprising at least an insulator and a reinforcing bar passing through the insulator and connected to both building structures In what consists of
The insulator is composed of at least three separate parts;
Two of the portions are a leg portion that extends below the entire length of the heat insulating structure, and a reinforcement portion that is disposed above the leg portion in the vertical direction and has the reinforcing bar, The reinforcing part has a shorter horizontal length than the leg part, and
One of the portions is at least one heat insulating structure which is a complementary portion that is aligned with the reinforcing portion in the horizontal direction and can be positioned above the leg portion in the vertical direction.   2. The heat insulating structure according to claim 1, wherein the leg portion has a height in a vertical direction substantially corresponding to a compression region on a lower side of the heat insulating structure in the assembled state.   The leg portion has a height substantially corresponding to the height of the precast panel, and the precast panel protrudes from the building structure and serves as a part of the structure that can be connected to the heat insulating structure. The heat insulation structure of Claim 1 or 2 which functions as a building structure.   4. The thermal insulation according to claim 1, wherein the leg has a vertical height which is approximately between ¼ and ½ of the overall height of the thermal insulation structure. Structure.   The heat insulation structure according to any one of claims 1 to 4, wherein the leg portion has a vertical height of approximately between 5 cm and 10 cm.   The reinforcing portion has a tensile bar provided for a seismic load as the reinforcing bar in a lower region, and the tensile bar is perpendicular to the insulator in a horizontal direction from the reinforcing part. The heat insulation structure as described in any one of Claim 1 to 5 which protrudes.   The said reinforcement part is a heat insulation structure as described in any one of Claim 1 to 6 which has the shear reinforcement provided for the seismic load as said reinforcement reinforcement.   The shear bar extends obliquely through the insulator and is curved so that the shear bar protrudes from the insulator at a substantially right angle at an exit region of the shear bar that exits the insulator. The heat insulation structure according to claim 7.   The heat insulation structure according to claim 7 or 8, wherein the shear line extends substantially in an upper region of the reinforcing portion.   The heat insulating structure according to claim 9, wherein the shear line extends over a range slightly shorter than the width of the reinforcing portion.   9. The thermal insulation structure according to claim 8, wherein the shear line extends obliquely through the insulator at an angle range of approximately 45 degrees with respect to the insulator plane.   The heat insulation structure according to claim 8, wherein the shear line extends in a vertical plane.   A precast concrete body comprising a precast panel having an added insulator, wherein the added insulator comprises the leg portion according to any one of claims 1 to 12, and the added insulation. A precast concrete body provided for constructing the heat insulating structure according to any one of claims 1 to 12 in cooperation with the reinforcing portion and the complementary portion.   The precast concrete body of claim 13, wherein the added insulator has approximately the height of a precast panel.   The precast concrete body according to claim 13 or 14, wherein the reinforcing bars of the heat insulating structure extend in a region on the upper side of the precast panel on the side of the heat insulating structure facing the precast panel.   At least one other heat insulating structure made of an insulator having an integrated reinforcing bar is joined to the precast concrete body, and is connected to the precast panel as a reinforcing bar integrated with the insulating body. 16. A compression receiver, a tensile bar extending horizontally in an upper region of the precast panel, and a shear bar extending at least partially through the precast panel. The precast concrete body described in 1.

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