KR20200076117A - Architectural Middle Insulation System and Construction Method of this - Google Patents

Abstract

The present invention relates to a middle insulation system for building and a construction method using the same, wherein the middle insulation system for building can improve construction and insulation performance, and more specifically, to a middle insulation system for building and a construction method using the same, wherein the middle insulation system for building can prevent a point type heat bridge and a linear type heat bridge of a wall structure by using a connector and an insulation block easily forming an insulation wall through mutual fit fastening in a block type and integrally construct foundation, floor, wall and roof structures to improve constructability, thereby improving a sense of beauty of a building and shortening a construction period.

Description

Architectural middle heat system and construction method using the same {Architectural Middle Insulation System and Construction Method of this}

The present invention relates to a construction medium heat system for construction and a construction method using the same, and more specifically, by inserting a construction insulation block in the middle of a wall to construct it, it is possible to more effectively in the internal and external disaster situations of buildings, such as fire, as well as insulation performance of buildings. In addition, it is related to the construction of a discontinued heat system for construction and a construction method using the same, which can increase the aesthetic value of a building through finishing of exposed concrete.

Recently, in Korea, there is an increasing demand to meet passive energy insulation standards in order to meet building energy regulation standards, which are equipped with exterior wall finishes to improve fire safety of buildings.

However, in order to meet both the aesthetics and thermal insulation performance of these structures, it is necessary to secure a finishing layer of a certain thickness or more along with the use of non-combustible insulation materials such as rock wool, and accordingly, various difficulties such as rapid increase in construction cost, deterioration of workability and air delay are pointed out It has been.

Also, as an alternative to this, recently, the technology for middle heat has been attracting attention, as in Korean Patent Registration No. 10-1214980, but construction defects due to external leakage of cement paste, etc., and the occurrence of linear thermal bridges and/or connecting agents (Pretai, Sepa) It is true that the problem of the deterioration of the value and insulation performance of buildings due to the occurrence of point thermal bridges (such as bold) has been continuously pointed out.

This ensures the safety of the building against fire, and at the same time, breaks off the point-type heat bridge and the linear heat bridge, and constructs a new concept of the construction of the discontinued heat wall system for construction that can meet the recently strengthened building energy reduction regulations. There has been an increasing demand for products and construction methods that can improve, shorten air and reduce construction costs.

Republic of Korea Registered Patent No. 10-1214980 Republic of Korea Registered Patent No. 10-1441399

The technical problem to be achieved by the present invention, the disadvantages pointed out in the conventional construction medium heat system and construction method using the same, that is, the location of the internal insulation block generated in the process of pouring and/or concrete paste that may occur in the construction stage It is to improve construction defects due to separation or random behavior of the linking agent, and to improve wall workability and thermal insulation performance of the wall.

In addition, the present invention has another object to maximize the energy reduction performance of buildings by minimizing a point-type heat bridge or a linear heat bridge through a connecting agent connecting the internal heat insulation block and the interior and exterior walls.

In addition, the present invention is to increase the safety of the building against disasters such as fire in the building by forming concrete walls on the outside and inside of the insulating block formed in the central portion of the wall, and at the same time, the outer and/or inner walls of the building are additionally Another purpose is to increase the value of the building by allowing it to have aesthetic value.

In order to achieve the object of the present invention described above, the middle heat system for construction according to the present invention includes: a basic module formed on an upper surface of the ground; A wall module formed on the upper surface along the basic module; And a roof module formed on an upper surface of the wall module, wherein the wall module comprises: an insulating block formed with a set thickness and width; A connector module in which a lower end portion is inserted into the upper surface of the heat insulating block and both ends are exposed to a predetermined length; And a flow path form fastened to one end of the connector module to form an interior space spaced apart from the heat insulation block by a predetermined distance, and each of the euroforms fastened to the heat insulation block, through the concrete poured in the interior space. It can be composed of a medium-sized heat system for construction characterized in that the outer wall and the inner wall are formed around the insulating block.

In addition, the connector module according to the present invention, constituting the body of the connector module, the connector is formed on each end of the receiving groove; And a flat tie formed long and flat in the longitudinal direction in which one end is inserted into the receiving groove, and the euroform is stably fastened through the wedge pin and the other end of the flat tie exposed to the outside. The connector, the lower end is inserted into the upper surface of the first insulating block, the upper end is inserted into the lower surface of the second insulating block adjacent immediately above the first insulating block, the first insulating block and the agent 2 It is possible to make the insulation block more tightly fastened, so that the insulation block does not behave arbitrarily even in the side pressure generated by pouring concrete, or the connector module comprises the connector A connector constituting the body of the module, wherein a receiving groove is formed at an extended end, and a bolt receiving hole is formed at an extended end; A first flat tie formed long and flat in a longitudinal direction in which one end is inserted into the receiving groove; A connection socket having one end bolted to the bolt receiving port; And a second flat tie formed long and flat in the longitudinal direction in which the connection socket and one end are inserted, wherein the connection socket is formed of an FRP material having a set strength and a low thermal conductivity, and thermal bridge through the connector module. It is possible to achieve the object of the present invention described above through the construction of a construction medium heat system for the construction characterized in that it can additionally add a blocking effect.

In addition, the wall module. It is also described above through the provision of an interrupted heat system for construction, characterized in that the structural safety of the building can be further reinforced by further including reinforcing bars reinforced in a pattern and shape set in the inner space formed between the heat insulating block and the flow path. It is possible to achieve the object of the present invention.

In addition, the basic module according to the present invention, a cast frame formed of a structural tree according to the plane set on the upper surface of the ground; A cast-in-place layer formed by pouring concrete into the inside of the cast-iron frame; An outer insulating plate formed to be spaced inward by a predetermined distance from the outer edge of the caster; A foundation insulating plate formed in close contact with the inside of the outer insulating plate; A basic reinforcing bar reinforced in a pattern and shape set on the upper portion of the foundation insulating plate; And

The insulating block and the concrete for the foundation that is poured into the space formed by the base insulating plate, wherein the outer insulating plate, the lower end of the wall module, through the insulating material connecting pin is inserted into the receiving groove formed in the longitudinal direction on the upper surface, The above-mentioned through the provision of a middle heat system for construction, characterized in that the lower surface of the heat insulating block to be located in the tightly fastened, so that the heat insulating block does not behave even in the side pressure generated by the poured concrete. It is possible to achieve the object of the invention.

In addition, the roof module, formwork sleeve form for forming a roof when the concrete is poured; A memo formed at a set position on the top surface of the slab form; And it is possible to achieve the object of the present invention through the provision of a medium-sized heat system for construction, characterized in that it can form a parapet wall, including a euroform attached to the upper surface of the memo diagram.

In addition, the method for constructing a suspended heat for building using any one of the above-mentioned suspended heat systems for building, comprising: a foundation module construction step of forming a foundation of a building on a set ground; A wall module construction step of forming a frame for forming a vertical wall on top of the basic module formed through the basic module construction step; A roof module construction step of forming a frame for forming a roof layer on an upper portion of the frame for forming a vertical wall formed through the wall module construction step; And pouring concrete into the space inside the frame formed through the wall module construction step and the roof module construction step, and after the poured concrete is cured, remove the euroform constituting the frame and reinforce the insulation of the opening. It is possible to achieve the object of the present invention described above through the provision of a method for constructing a discontinued heat system for construction, characterized in that it includes a concrete pouring and an insulating reinforcement step.

In addition, the foundation module construction step, the cast-iron frame forming step of forming a cast-frame on the upper surface of the ground; A cast-in-place layer construction step of pouring cast-in concrete along the cast-iron frame to form a cast-in-place layer and flattening the cast-in-place layer; The outer insulating plate forming an outer index plate by attaching a heat insulating material having a certain thickness to the upper surface of the cast-in-place layer and the foundation insulating plate forming a separate index plate inside the outer insulating plate at the same height as the outer insulating plate, respectively, the casting cast layer Construction step of the basic insulation plate attached to; A lower end wall construction step of positioning the insulation block in the longitudinal direction along the upper surface of the outer insulation plate; A basic reinforcing bar reinforcement step of reinforcing a basic reinforcing bar in a space formed through the bottom insulating wall formed through the insulating block and the foundation insulating plate; And a foundation concrete pouring step of pouring concrete for forming a foundation structure in a space formed through the bottom insulating wall and the foundation insulating plate, wherein the foundation insulating plate construction step includes a length on the top surface of the outer insulating plate. After forming the guide groove in the direction, further comprising the step of inserting a heat insulating material connecting pin, the lower end wall construction step, when placing the insulating block in the longitudinal direction on the upper surface of the outer insulating plate, the lower portion of the insulating block By setting the connecting pin receiving groove formed on the surface to be connected with the insulating material connecting pin, the position where the insulating block is formed to form the bottom wall of the wall by the concrete side pressure that can be generated in the concrete pouring and insulating reinforcement step (outer insulating plate or foundation It is also possible to achieve the object of the present invention described above through the provision of a method for constructing a discontinued heat system for construction, characterized in that it is supported so as not to deviate or behave randomly on a set top surface of the insulating plate).

In addition, the wall module construction method includes: a wall assembly construction step of sequentially stacking insulating blocks in a length direction and a height direction along a set upper surface of the foundation module; A flat tie construction step of inserting and receiving a flat tie into a connector exposed inside the stacked insulating block; An inner wall reinforcing bar step of reinforcing the reinforcing bars for the inner wall in a pattern and shape set as a guide for the flat tie protruding toward the inside of the heat insulating block; Including the euroform construction step of fastening the euroform while maintaining a predetermined distance with one end of the flat tie formed protruding inward, the flat tie is inserted into the center of the four neighboring the euroforms that the corners are in contact with each other, a circular pin And it is possible to consider the purpose of the present invention to provide a construction method for a medium-sized heat system for construction, characterized in that it is possible to flatten the neighboring Euroform through a wedge pin fastened to the insertion groove of the flat tie.

The construction interruption heat system for construction according to an embodiment of the present invention and the construction method using the same provide support for ensuring a safer durability and fireproof performance in a disaster situation such as aesthetics and fire by exposed concrete, and at the same time improve the insulation performance of the building. It is possible to provide an effect that can be significantly improved.

In addition, it is possible to support a variety of interior and exterior wall finishing, it is possible to add the economic value of the building through the application of the building medium-heat system according to the present invention.

In addition, it is possible to dramatically improve the workability through the construction of the discontinued heat system for construction and the construction method using the same, which can make the sequential lamination and fastening of the insulating blocks composed of the modular type, and at the same time, it has the effect of reducing air and reducing construction costs. It has the effect of being able to.

However, it should be understood that the effects of the present invention are not limited to the above-described effects, and include all effects that can be deduced from the configuration of the invention described in the detailed description of the present invention or in the claims.

1 is a view showing the overall shape and detailed configuration of the heat insulation block module, the connector module of the middle heat system according to an embodiment of the present invention, respectively.
FIG. 2 is a view showing a basic (floor) portion of a middle heat system for construction according to an embodiment of the present invention, and FIG. 3 is a view of a roof (ceiling) portion of a middle heat system for construction according to an embodiment of the present invention. It is a figure specifically showing.
4 is a view showing the structure of an insulating block module constituting a middle heat system according to an embodiment of the present invention.
5 is a view showing the structure of a connector module constituting a middle heat system according to an embodiment of the present invention.
6 to 30 are diagrams showing the construction method of the construction interruption heat system for construction using the interruption heat system for construction according to an embodiment of the present invention step by step.

Hereinafter, the present invention will be described with reference to the accompanying drawings. However, the present invention may be implemented in various different forms, and thus is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and like reference numerals are assigned to similar parts throughout the specification.

Throughout the specification, when a part is said to be "connected (connected, contacted, coupled)" with another part, it is not only "directly connected", but also "indirectly connected" with another member in between. "It includes the case where it is. Also, when a part “includes” a certain component, this means that other components may be further provided, not excluding other components, unless otherwise specified.

The terms used herein are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this specification, terms such as “include” or “have” are intended to indicate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, and that one or more other features are present. It should be understood that the existence or addition possibilities of fields or numbers, steps, operations, components, parts or combinations thereof are not excluded in advance.

Figure 1 (a) is an overall view of the middle heat system 10 according to an embodiment of the present invention, Figure 1 (b) is a detailed configuration of the insulating block module 100, Figure 1 (c) is a connector module It is the figure which shows 300 each.

FIG. 2 is a view showing a basic (floor) portion of a suspended heat system for construction according to an embodiment of the present invention, and FIG. 3 is a view of a roof (ceiling) part of a suspended heat system for construction according to an embodiment of the present invention. It is a figure specifically showing.

4 is a view showing the structure of an insulating block module 100 according to an embodiment of the present invention, and FIG. 5 is a view showing the structure of a connector module 300 according to an embodiment of the present invention.

1 to 5, the middle heat system 10 according to an embodiment of the present invention includes a wall module 100, a base module 500, and a roof module 700.

More specifically, the present invention, the foundation module 500 formed on the top surface of the ground, the wall module 100 formed on the top surface along the foundation module 500 and the roof module formed on the top surface of the wall module 100 It can be a building heat-dissipating system 10 including 700.

The wall module 100 is a module constituting the wall of the suspended heat system 10 for construction according to the present invention, and the lower end is inserted into the upper surface of the insulating block 110 and the insulating block 110 formed with a set thickness and width. It is accommodated and both ends are fastened with the connector module 300 exposed to a set length to the outside and one end of the connector module 300 to form an inner space in a state spaced apart from the insulating block 110 by a predetermined distance. Interruption heat system for construction, comprising a block (110) and a Euroform (130) that are fastened to each other, and forming an outer wall and an inner wall with the concrete (B) being poured into the interior space around the insulating block (110). It can be (10).

To this end, the wall module 100 according to the present invention may include an insulating block 110 and a Euroform 130, and a connector module 300 and a wall reinforcement 160 interconnecting them.

The insulating block 110 constitutes a part of the wall of the middle heat system for construction 10 according to the present invention, and is made of a material such as a bead method insulating plate (EPS, carbon reinforced EPS), and provided in various heights and shapes as required. Can be. However, the insulating block 110 according to an embodiment of the present invention is an organic type (Butyl stearate, Paraffin C16~C18, Capric-Lauric acid, etc.) or an inorganic type (KF·4H2O, Mn(NO3)2·) to have heat storage performance. 6H2O, etc.) Phase change substances or eutectic mixtures (66.6% CaCl2 6H2O+33.3% MgCl2 6H2O, etc.) can be included in part or all (by utilizing latent heat of the phase change material to absorb external thermal changes to provide heat storage function) have.

As shown in Figure 1 (b) and 4, in the case of the insulating block 110 according to the present invention, the upper surface (in the case of the lower surface in the upper surface so as to be fastened to the other insulating block 110 adjacent to the top and bottom) An insertion hole or the like may be formed on the lower surface of the protrusion and the corresponding position) and a pattern such as a curved shape having a certain height on the side surface may be formed, through which the neighboring insulating blocks 110 are vertically and horizontally, It is easy to fasten the left and right mutually. That is, the lower surface of the first insulating block 110 adjacent to the upper and lower parts and the corresponding neighboring surfaces (the upper surfaces of the second insulating block located directly below) are mutually fitted (fit-fastened), and correspondences formed on the side surfaces on both sides. Another insulating block 110 is interleaved and fastened (fit-fastened) through the height pattern to form a plurality of insulating blocks 110 to form a wall surface in a flat plane (the adjacent insulating blocks 110 vertically, horizontally and horizontally fit each other) It is possible to more easily form a vertical “insulation wall” through fitting, etc. (See Fig. 2) By doing this, it is possible to omit a separate flattening operation, and at the same time, easy fastening (fitting) of a plurality of insulating blocks 110. Or, for example, a lego (LEGO block) is possible, such as a custom fastening, so as to improve the constructability of the wall construction and shorten the construction period through it. In addition to improving durability, it also has the advantage of significantly improving the insulation of the building through the fastening structure between the tight insulating blocks 110.

Euroform (130, EURO FORM) refers to a pre-formed formwork (formwork) to be easily installed and dismantled in various types of reinforced concrete structures. In order to more easily correspond to the standardized Euroform 130 (cross-linking), the insulating block 110 according to the present invention may be provided with the width and width of the Euroform 130.

The connector module 300 according to the present invention constitutes the body of the connector module 300, and at both ends there is a connector 310 in which “receptive grooves” are respectively formed, and the “receiving grooves (eg, +-shaped receiving grooves). It may be)) in the longitudinal direction in which one end is inserted into a long and flat formed flat tie 330. In this case, the euro form 130 is to be stably fastened through the other end of the flat tie 330 exposed to the outside and the wedge pin 350 and the like, while the connector 310 is the first insulating block 110 The lower end is inserted and accommodated in the upper surface, and the upper end is inserted and accommodated in the lower surface of the second insulating block 110 adjacent immediately above the first insulating block 110, so that the first insulating block 110 and the second insulating layer Block of construction, characterized in that the block 110 is to be more tightly fastened, so that the insulating block 110 does not randomly move (deviate from any position, etc.) even after the side pressure generated by the poured concrete (B). It is possible to provide a thermal system 10.

In addition, unlike this, the connector module 300 according to the present invention constitutes the body of the connector module 300, and an “accommodating groove” is formed at an end extending inside, and an “bolt receiving port” at an end extending outside. Connector 310 is formed, the first flat tie (330-1) is formed in a long and flat in the longitudinal direction, one end is inserted into the "accommodating groove", one end bolted to the sinker "bolt inlet" The socket 320 and the connection socket 320 and a second flat tie 330-2 formed long and flat in a longitudinal direction in which one end is inserted, but the connection socket 320 has a set strength and a thermal conductivity. Silica aerogels, alumina, carbon aerogels, etc. may be applied to low or synthetic resin (FRP, etc.) materials or synthetic resins on all or part of the surface, and through this, a thermal bridge blocking effect through the connector module 300 may be additionally added. It is also possible to configure a construction medium heat system (10) characterized in that (see Fig. 5).

To this end, the connector module 300 according to the present invention is a fastening module capable of interconnecting the heat insulating blocks 110 and the euroforms 130 spaced apart at predetermined intervals on the left and right sides of the heat insulating block 110, respectively. When concrete is poured into the space formed between the block 110 and the euroform 130, the random behavior of the insulating block 110 due to lateral pressure of the poured concrete is more effectively blocked, and thermal bridges (linear and/or pointed) are blocked. It can be configured to block additionally. To this end, the connector module 300 according to the present invention may include a connector 310, a connection socket 320, and a flat tie 330.

The connector 310 according to the present invention, as shown in Figure 5, the left and right "+-shaped receiving groove" to which each end of the flat tie 330 can be inserted and fastened is formed on the left and right sides, the main body is the top ( The upper portion) and the lower portion (lower portion) may be formed separately. In this case, the flat tie 330 can be fastened in the horizontal or vertical direction as necessary through the formation of the "+-shaped receiving groove" formed on the left and right sides of the connector 310, so that it can be freely responded to according to the site situation (Fig. 13).

In addition, the connector 310 according to the present invention, as shown in Figure 5, "+-shaped receiving groove" instead of the "bolt fastening groove" is formed, the connection socket that can be screwed through the "bolt fastening groove" ( 320) may be fastened to one end or the other end of the connector 310. That is, the connection socket 320 according to the present invention has one end connected to the connector 310 through a screw connection, and the other end may be a socket-type connection tool for receiving and fastening the flat tie 330.

In addition, the connector 310 according to the present invention may be formed of a material having a strength above a certain level, such as FRP, and having a low thermal conductivity, through which heat or cold air transferred through the outer wall and/or the inner wall, that is, a thermal bridge ( It is possible to more effectively block linear thermal bridges or point thermal bridges.

The connection socket 320 according to the present invention may be formed of a material having low thermal conductivity, such as synthetic resin (FRP, fiber-reinforced plastic, fiber-reinforced plastic, composite material, etc.) material or plastic, and in particular, Euroform 130 for forming an outer wall It is preferentially fastened to the other end of the flat tie 330 of the steel material connected to the steel material, and again, one end is connected to the connector 310, thereby allowing heat or cold to be transmitted through the flat tie 330. It can be additionally blocked, and through this it is possible to additionally prevent the point bridge and/or linear bridge via the flat tie 330.

In addition, the connection socket 320 according to the present invention is a silica airgel (a number of nano-porous layers are formed inside) on all or part of a portion exposed to the outside in a state of fastening (bolt-nut fastening structure, etc.) with the connector 310 ) The layer may be additionally coated (or applied) to further enhance thermal insulation performance. In this case, the silica airgel is a supercritical drying process of the airgel obtained by the condensation reaction of Alkylorthosilicate at a high temperature (the surface -OH functional group reacts with a solvent to have a methoxy (-OCH3)x functional group to form hydrophobicity). You can make it hydrophobic by going through it.

In addition, the connector 310 according to the present invention may be partially accommodated (lower end) is inserted into the set position of the upper end of the insulating block 110 (see FIG. 4). In addition, the connector 310 exposed to the upper portion may be inserted and accommodated in a set position at the lower end of the second insulating block 110 that is adjacent to the upper portion. Through this, the first insulating block 110 and the second insulating block 110 that are tightly fastened up and down can be more tightly fastened through the connector 310 (see FIG. 17 ).

Accordingly, the insulating block 110 according to an embodiment of the present invention is inserted into the set position at the upper end and is fastened to the second insulating block 110 adjacent to the upper side through the connector 311 to be fastened (FIG. 16) Reference), “+-shaped receiving grooves” or “bolt fastenings formed at the ends of the connectors 310 exposed to the outside on both sides of the left and right sides in a state in which vertical and middle heat insulating block walls are mutually fastened between neighboring insulating blocks 110 Home” again by allowing the flat tie 330 to be fastened directly or through a connection socket 320 (see FIGS. 17 and 24 ), the wall reinforcement 160 on the left and right sides with respect to the insulating block 110. 18 and 25) and the euro form 130 are more easily arranged and fastened, and concrete can be more easily poured into the space between the heat insulation block 110 and the euro form 130 to form the wall module 100. do.

The euro form 130 is fastened to one end of the flat tie 330. To this end, the euro form 130 may be formed with a receiving groove 130a at a position corresponding to the fastening groove 330a formed at one end of the flat tie 330, and the fastening groove 330a and the receiving groove 130a. Finally, through the wedge pin 350 partially penetrating, the insulation block 110, the connector module 300, and the euroform 130 may be sequentially engaged (see FIG. 4).

With this, the wall module 100 according to the present invention. As shown in FIG. 20, the four neighboring Euroforms 130 are stably fastened with the flat tie 330 at a portion such as a corner that is in contact with each other, and at the same time, the inner side of the fastening groove 330a of the flat tie 330. Four neighboring Euroforms 130 are vertical wall surfaces through a circular plate-shaped circular pin 350a formed at a position where a groove that can be inserted into and inserted into and a wedge pin 350 inserted into the fastening groove 330a are inserted. With reference to, it is possible to form and maintain a stable plane of the formwork. In addition, in this case, the flat tie 330 can be inserted and fastened in the horizontal or vertical direction to the receiving groove of the connector 310 (which may be a “+-shaped receiving groove”) as necessary, the fastened Euroform 130 ) More elastically according to the fastening direction and shape, etc., the fastening direction of the circular pin 350a and the wedge pin 350 can also be adjusted.

The wall reinforcing bars 160 are directly inserted into the ends of the connectors 310 that are exposed to the outside and the inside, respectively, in a tightly coupled state adjacent to each other of the plurality of insulating blocks 110 (via the “+-shaped receiving groove” described above). ) Or screw fastening (via a connection socket 320) refers to a reinforcing bar that is reinforced according to a preset pattern along a plurality of flat ties 330 exposed by a set length to the outside and the inside, respectively. The wall reinforcing bar 160 integrally forms a reinforced concrete wall after the poured concrete is cured, and can support the building, internal and external static loads, and dynamic loads together with the concrete. The wall reinforcing bar 160 according to the present invention is an outer wall reinforcing bar (formed on the outside of the middle heat insulating wall formed of the insulating block 110) and an inner wall reinforcing bar (the insulating block 110) based on the insulating block 110. It can be divided into each formed on the inside of the heat-insulating barrier wall formed).

In addition, the wall module 100 according to the present invention does not form a separate heat insulation block 110 and a Eurofoam 130 in the position of the opening A such as a window or a separate ALC panel in the opening of the window or the like to improve heat insulation performance. (Autoclaved Lightweight Concrete panel) may be additionally attached (see FIG. 31).

The base module 500 is to form the bottom of the middle-use heat system 10 for construction according to the present invention, it is formed on the lower end of the above-described wall module 100 (see FIG. 2).

The foundation module 500 according to the present invention may include a cast frame 510, cast cast layers 520 and 530, an outer insulating plate 540, a basic insulating plate 550 and a basic reinforcing bar 560.

The cast iron frame 510 is a reference frame (guide) used for the flattening of the foundation and/or the floor, and may be formed in a manner of fixing structural wood to the ground using piles or the like.

The first cast-in-place layer 520 refers to a concrete (or cement) layer poured along the installed cast-in-place 510, and is flatly constructed according to the height of the cast-in-place 510, and the second cast-in-place layer 520 530) refers to a base floor layer that is flatly constructed using rubble or concrete (or cement) at the same height as the first cast-off layer 520 inside the first cast-off layer 520. The base floor plate according to the present invention is formed through the first cast-off layer 520 and the second cast-off layer 530. However, one or more of the cast iron 510, the first and/or the second cast cast layers 520 and 530 may be omitted depending on the state of the ground or the like.

The outer insulating plate 540 refers to an insulating material such as expanded polystyrene (EPS) or extruded polystyrene (XPS) formed to have a set height along the top surface of the first cast-off layer 520 (see FIG. 8 ). In this case, the outer insulating plate 540 may be formed with a “guide groove” capable of accommodating the insulating connection pin 541 on the set upper surface.

Insulating material connecting pin 541 is partially (lower end) is inserted into the outer insulating plate 540 through the "guide groove", while some (upper part) can be accommodated in the lower surface of the above-described insulating block 110. have. To this end, the insulating block 110 according to the present invention may have a separate "connection pin receiving groove" formed narrow and long along the longitudinal direction on the lower surface (see FIG. 9), through which the wall module 100 The insulation blocks 110 located at the shortest part are formed to be attached to the upper surface of the outer insulation plate 540, and the insulation connection pins are formed to be exposed on the upper surface of the outer insulation plate 540 along the longitudinal direction for more stable attachment. The lower surface of the insulating block 110 to which the lower surface is fastened through 541 and the upper surface of the outer insulating plate 540 may be more closely attached.

In addition, a plurality of mutually adjacent insulating blocks 110 and the outer insulating plate 540 of the base module 500 are stably fastened in the longitudinal direction located at the bottom end of the wall module 100 through the insulating material connecting pin 541. In addition, it is possible to prevent the leakage of the concrete paste through the lowermost portion where the load is concentrated while preventing the insulation block 110 from randomly moving or randomly deviating from the set position even after the side pressure of the concrete being poured.

The base insulation plate 550, as shown in FIG. 10, has a heat insulating plate formed in the inner space partitioned by the outer insulation plate 540 at the same height as the outer insulation plate 540 on the upper surface of the second cast-off layer 530. Refers to. However, the base insulating plate 550 according to the present invention is provided as a separate insulating plate from the outer insulating plate 540, or provided as an insulating plate (EPS, XPS material, etc.) having a set thickness and width integrally formed with the basic insulating plate 540. It can also be achieved through this.

The basic reinforcing bar 560 refers to a reinforcing bar structure that is reinforced according to a gap and a pattern set on the inner side of the insulating block 110 and the upper surface of the basic insulating plate 550, and after reinforcing the basic reinforcing bar 560, the basic concrete Poured, the foundation module 500 of the building medium heat system 10 according to the present invention is formed. In addition, after curing of the foundation concrete is completed, a memo diagram may be installed as needed (see FIG. 16 ), and further, the leakage of paste to the lowermost portion of the wall module 100 may be further prevented.

The roof module 700 may include a slab form 710 and a roof reinforcement 760.

The slab form 710 refers to a slab formwork for ceiling formation formed along the uppermost end of the inner flow path form 130 of the preformed wall module 100, and has a predetermined thickness that can easily correspond to the construction of the inner plane, etc. Plywood or the like can be used.

The roof reinforcing bar 760 refers to a reinforcing bar structure that is reinforced according to a gap and a pattern set on the inner surface of the insulating block 110 and the upper surface of the slab form 710, and then forming the wall module 100 and/or the parapet wall A concrete (B) pour space is formed together with the Euroform (130, see FIG. 23), and then the concrete (B) is sequentially poured (see FIG. 28), thereby preventing the construction of the interrupted heat system 10 for construction according to the present invention. ) Will form a parapet and/or roof.

Hereinafter, with reference to FIGS. 6 to 30 will be described a construction method using a suspended heat system for construction 10 according to the present invention.

Construction method using a suspended heat system for construction according to the present invention includes a basic module construction step (S100), a wall module construction step (S200), a roof module construction step (S300) and concrete pouring and heat insulation reinforcement step (S400). . That is, the construction method using the suspended heat system 10 for construction according to the present invention includes a basic module construction step (S100) and a basic module construction step (S100) formed through the foundation module construction step (S100) to form the foundation of the building on the set ground. A wall module construction step (S200) of forming a frame for forming a vertical wall on the upper part of the frame (an interior space for pouring concrete formed through the insulating block 110 and the flow path form 130 spaced apart on both sides), Roof layer forming frame on top of the vertical wall forming frame formed through the wall module construction step (S200) (forming the interior space for pouring concrete formed through the euroform 130 for forming the parapet and the insulating block 110) Concrete (in the interior space of the frame (vertical wall forming frame and roof layer forming frame)) formed through the roof module construction step (S300) and the wall module construction step (S200) and the roof module construction step (S300) forming a ( B) pouring, and after pouring the concrete (B) is cured, the concrete pouring and insulation reinforcement step (S400) is performed to remove and reinforce the insulation of the building openings such as windows and windows, which form the frame. It can be designed by the construction method of the middle heat, characterized in that the construction.

Hereinafter, the construction method using the suspended heat system 10 for construction according to the present invention will be described in more detail by dividing each step.

The foundation module construction step (S100) includes the cast-iron frame construction step (S110), the cast-in-place layer construction step (S120), the foundation insulation plate construction step (S130), the lowermost wall construction step (S140), the basic rebar reinforcement step (S150), and the foundation. Concrete pouring step (S160) may be included.

Hereinafter, the basic module construction step (S100) will be described in more detail with reference to FIGS. 6 to 15.

6 is a view schematically showing the construction step S110 (S110) according to the present invention.

The cast iron frame 510 according to the present invention is an initial step for forming the foundation of the suspended heat system 10 for construction in a flat manner, after confirming the level of the entire ground using structural timber, piles and/or rebar chips, etc. Refers to a step of fixing structural trees having a constant height to each other by a predetermined width along a plane of a predetermined structure.

7 and 8 is a view showing a cast-in-place layer construction step (S120) according to the present invention.

After the first cast-off layer 520 is installed, the cast-in-place layer 520 is formed through concrete pouring in the interior space partitioned by the cast-off frame 510. At this time, it is preferable that the operation of flattening the first cast-in-place layer 520 is performed in the same manner as the height of the cast-off frame 510 using a trowel or the like. The second cast-off layer 530 refers to a step of filling the inner space of the cast-off frame 510 with concrete or rubble and performing a work of flattening the floor in the same manner as the height of the first cast-off layer 520. However, as shown in FIGS. 7 and 8, in the step of constructing the cast-off layer according to the present invention (S120 ), after forming the first cast-in-place layer 520, the second cast-in-place layer 530 may be sequentially formed. However, it can also be integrally formed at once.

9 and 10 is a view showing a base insulating plate construction step (S130) according to the present invention.

The foundation insulation plate construction step (S130) may be divided into steps of installing the outer insulation plate 540 shown in FIG. 9 and the installation of the foundation insulation plate 550 shown in FIG. 10, respectively. More specifically, the outer insulating plate 540 is spaced inward by a predetermined distance from the above-described first cast-off layer 520, but is formed along the top surface of the first cast-off layer 520 (also of the outer insulating plate 540) The upper surface may include a step in which a heat insulating material connecting pin 541 is inserted along the “guide groove” formed in the longitudinal direction), and then the upper surface of the second cast-off layer 530 and the inner side of the outer insulating plate 540 In accordance with the step of constructing the foundation insulating plate 550 in close contact. However, the insulation plates (EPS, XPS) having a predetermined thickness may be formed in close contact with the upper surfaces of the cast-off layers 520 and 530 without being separated from the separate outer insulation plates 540 and the foundation insulation plates 550. .

11 and 12 is a view showing the construction step (S140) of the lowermost wall using the suspended heat system 10 for construction according to the present invention.

The bottom-most wall construction step (S140) refers to a step of positioning the heat insulating block 110 constituting the bottom end of the wall module 100 while maintaining a horizontal surface in the longitudinal direction along the outer insulation plate 540. At this time, the upper end of the insulation connecting pin 541 inserted into the upper surface of the outer insulating plate 540 so that the lowermost insulating block 110 constituting the middle heat system 10 by the side pressure of the poured concrete does not deviate from the set position It is preferable to construct the insulating block 110 so as to be inserted into the “connection pin receiving groove” formed at a set position of the lower surface of the lowermost insulating block 110. Thereafter, along the inside of the insulating block 110, the base insulating plate 551 may be additionally installed in close contact with the upper surface of the basic insulating plate 550. In this case, the second base insulating plate 551, which is additionally overlapped with the lower base insulating plate 550, is preferably constructed to be misaligned so that no vertically falling trunk eyes are formed. In addition, if necessary, the insulating block 110 constituting the lowermost portion may be formed by stacking one layer or two or more layers to form a required height (see FIG. 11 ).

13 and 14 is a view showing a state of the basic reinforcement step (S150) using a medium-heat construction system 10 according to the present invention.

The basic reinforcement step (S150) inserts a flat tie 330 having a certain length into the “+-shaped receiving groove” formed on one side of the connector 310 pre-fastened with the insulating block 110 and flat tie 330 inward. ) May be exposed (see FIG. 13) and the step of reinforcing the foundation reinforcing bar 560 in a pre-designed pattern and structure using a flat tie 330 connected to the connector 3310 as a support (see FIG. 14 ). have. In addition, when the flat tie 330 is fastened to the “+-shaped receiving groove” of the connector 310, as shown in FIG. 13, the flat tie 330 to the “+-shaped receiving groove” through a fastening means such as a separate bolt. One end of the can be made to be more tightly and stably fastened. In FIG. 13, the flat tie 330 is fastened to the “+-shaped receiving groove” in the vertical direction, but may be fastened to the “+-shaped receiving groove” in the horizontal direction as needed. In addition, when reinforcing the foundation reinforcing bar 560, for maintaining the weight and shape of the reinforcing bar 560, if necessary, it may further include the step of forming a separate temporary material on the upper surface of the foundation insulating plate (550, 5510).

15 is a view showing a foundation concrete pouring step (S160) using a medium-heat construction system 10 according to the present invention.

The foundation concrete pouring step (S160) pours the foundation concrete 570, which is poured into the interior space formed by sidewalls formed through the heat insulating blocks 110 with the base insulating plates 550 and 551 as the lower surface, and is poured. After the concrete 570 is cured, the step of forming a memodo 580 at a set position (reflecting the boundary between the outer and inner walls) of the upper surface.

The wall module construction step (S200) may include a wall assembly construction step (S210), a flat tie construction step (S220), an inner wall rebar reinforcement step (S230), and an inner wall euroform construction step (S240).

Hereinafter, the wall module construction step (S200) will be described in more detail with reference to FIGS. 16 to 20.

16 is a view showing a wall assembling construction step (S210) using a middle heat system for construction (10) according to the present invention.

The wall assembling construction step (S210) refers to a construction step of stacking the insulating block 110 in correspondence with the height of the building to the upper part of the lowermost insulating block 110 layer formed in the basic module construction step (S100). At this time, the upper and lower neighbors of the first insulation block 110 and the lower part of the second insulation block 110 can be more tightly and stably fastened through the connector module 300 (for example, standardized Lego and The same prefabricated form), more easily the contractor can be constructed by stacking vertical walls through a plurality of insulating blocks 110 through a fitting fit. In addition, as shown in FIG. 15, the connector 310 of the connector module 300 maintains a state in which one end is exposed to the outside in a state where the insulating block 110 is fastened.

17 is a view showing a flat tie construction step (S220) using a suspended heat system for construction 10 according to the present invention.

In the flat tie construction step (S220), after the wall assembly is completed through the insulating block 110, each flat tie 330 is placed in the receiving groove of the connector 310 exposed to the inside (which may be a “+-shaped receiving groove”). ) Refers to the step of fastening (separate piece-bolt fastening can be added if necessary) (see FIG. 13 ).

18 is a view showing an inner wall reinforcing bar reinforcement step (S230) using a middle-use heat system 10 for construction according to the present invention.

The inner wall reinforcement step (S230) refers to the step of reinforcing the structural wall reinforcement 160 in a pattern and shape set as a guide for the pre-installed flat tie 330.

19 and 20 is a view showing a construction step (S240) of the inner wall flow path form using a middle heat block system 10 for construction according to the present invention.

The Euroform construction step (S240) is formed by fastening and forming the Euroform 130 of the first stage on the upper surface of the memo diagram 580 formed through the basic module construction step (S100) (see FIG. 19), and at one end of the flat tie 330. Insert the wedge pins 350 into the formed insertion grooves 330a, and if necessary, the fastening of the four corners of the euroform 130 can be adjusted to be flat with each other). It includes a construction step (see Fig. 20) in which the euro form 130 is stacked correspondingly while maintaining the set interval. In this case, the flat tie 330 is inserted into the center of the four neighboring euroforms 130, the corners of which are in contact with each other, and the wedge pin is fastened to the circular pin 350a and the insertion groove 330a of the flat tie 330. There is also a feature that can be configured as a medium-use heat system for construction, characterized in that the flattening of the neighboring Euroform 130 through 350 is possible (see Fig. 20).

The roof module construction step (S300) is a slab form construction step (S310), a slab reinforcement step (S320), a parapet wall formwork construction step (S330), a connection socket construction step for the outer wall (S340), and an outer wall reinforcement step ( S350), an opening construction step (S360) and an outer wall euroform construction step (S370) may be included.

FIG. 21 shows a slab form construction step (S310) using a suspended heat system 10 for construction according to the present invention, FIG. 22 shows a slab reinforcement step (S320), and FIG. 23 shows a parapet wall formwork construction step (S330). It is the figure which respectively shows.

The slab form construction step (S310) is a step of installing a slab foam 710, which is a temporary material for forming a roof in an indoor space, as much as a height set to the inside of a wall formed through the heat insulation block 110. The temporary material is manufactured through the like, and the manufactured temporary material is placed on the upper surface of the euroform 130 for forming the inner wall.

Thereafter, the slab reinforcement step S320 of reinforcing the slab reinforcement 760 to the upper portion of the slab form 710 in a predetermined pattern and structure is performed.

Thereafter, the parapet wall formwork construction step (S330) is performed. In the parapet wall formwork construction step (S330), a memo diagram 580 may be additionally formed at a set position on the top surface of the slab foam 710 as required, and the euro foam 130 is required on the top surface of the memo diagram 580. Stacked by height to form a formwork structure for the formation of a (roof) parapet wall.

24 is a view showing a construction step (S340) of the connecting socket for the outer wall using the suspended heat system 10 for construction according to the present invention.

The connection socket construction step (S340) for the outer wall is a construction step similar to the above-described flat tie construction step (S220), and the connector 310 exposed to the outside of the heat insulation block 110, which is a vertical wall formed by abutting each other in close contact with each other, Refers to the construction step of fastening the flat tie 330 through the connection socket 320 at the end of the. In the same way as the inner wall, a “+-shaped receiving groove” is formed at one end of the connector 310, and a form for fastening and receiving one end of the flat tie 330 in the “+-shaped receiving groove” can also be used, but from outside air For additional reinforcement of thermal insulation performance, a separate connection socket 320 formed of a synthetic resin material (which may be FRP or the like) or a material having low thermal conductivity, such as plastic, is easily adopted, and the connection socket 320 is additionally reinforced. ) One end is preferentially fastened with one end of the connector 310 exposed to the outside (screw-bolt fastening, etc.), and again adopts a structure in which the flat tie 330 is accommodated at the other end of the connection socket 320. It is desirable to do.

25 is a view showing a reinforcement step (S350) of the outer wall reinforcement using the middle heat building system 10 according to the present invention.

The outer wall reinforcement step (S350) is guided by the flat tie 330 connected to the connector 310 through the connection socket 320, and the wall reinforcement 160 to be attached to the inside of the outer wall of the building in a predetermined pattern and structure ). At this time, a part of the inner wall reinforcing bar and a set part of the outer wall reinforcing bar (for example, a top end, a reinforcing bar for forming a rooftop parapet, etc.) may be interconnected and fastened as necessary to reinforce structural safety of the building.

26 is a view showing a construction step (S360) of the opening using the suspended heat system for construction 10 according to the present invention.

In the opening construction step (S360), a separate formwork is attached to the shape, shape, and size of the opening (A) of the building, such as a window or window, so that the whole or part of the opening is blocked or blocked by pouring concrete. Refers to the steps taken in advance so as not to.

27 is a view showing a construction step (S370) of the outer wall flow path using the middle heat block system 10 for construction according to the present invention.

The outer wall euroform construction step (S370) is the same as the above-described euroform construction step (S240) through the flat tie 330 through the insulating block 110 and a plurality of euroform 130 that is fastened at a predetermined interval to form the outer wall concrete It refers to the step of forming a pour space.

The concrete pouring and insulating reinforcement step (S400) may include a concrete pouring step (S410), a Euroform dismantling step (S420), and an insulating reinforcement construction step (S430).

Figure 28 is a concrete pouring step (S410) using a suspended heat system for construction according to the present invention (10), Figure 29 is a Euroform dismantling step (S420), Figure 30 is a diagram showing the insulation reinforcement construction step (S430), respectively to be.

Concrete pouring step (S410) is spaced apart by a predetermined distance (via connector module 300) on the inside and outside, centered around the heat-insulating block 110 and the heat-insulating block 110, which are formed through the heat-insulating block 110, respectively. Refers to the step of pouring concrete (B) mixed according to a set ratio of cement, aggregate and/or sand, etc. in the space formed between the inner and outer flow paths 130.

Euroform dismantling step (S420) refers to a working step of dismantling the formwork, which was used for forming the inner and outer walls after the concrete poured in the concrete pouring step (S410) is sufficiently cured. In addition, in the case of the outer wall, after the dismantling of the Euroform 130, the connection socket 320 is directly connected to the connector 310, so that concrete is poured, and the groove formed as a pattern at regular intervals on the exposed concrete without additional construction. As a result, it is possible to further increase the aesthetics of the externally exposed concrete.

In the case of the last thermal insulation reinforcement construction step (S430), it may include a construction step of attaching an ALC panel for additional fire safety and thermal insulation performance improvement to the opening (A) such as a window.

The above description of the present invention is for illustration only, and a person having ordinary knowledge in the technical field to which the present invention pertains can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is indicated by the following claims, and all modifications or variations derived from the meaning and scope of the claims and their equivalent concepts should be interpreted to be included in the scope of the present invention.

10: Construction interruption heat system
100: wall module
110: insulation block (connection pin receiving groove)
130: Euroform (130a: accommodation groove)
160: wall reinforcement
300: connector module
310: connector (+ shaped receiving groove)
320: connection socket
330: flat tie (330a: insertion groove)
350: wedge pin (350a: round pin)
500: basic module
510: castaway
520, 530: castaway layer
540: outer insulation plate (guide groove)
541: insulating material connecting pin
550: base insulation plate
560: Basic rebar
570: foundation concrete
580: Memo also
700: roof module
710: slab form
760: Roof reinforcement

Claims (9)

A foundation module formed on the ground surface;
A wall module formed on the upper surface along the basic module; And
In the middle heat system for construction comprising a roof module formed on the upper surface of the wall module,
The wall module,
An insulating block formed with a set thickness and width;
A connector module in which a lower end is inserted into the upper surface of the heat insulating block and both ends are exposed to a length set to the outside; And
It includes a euro form that is fastened to one end of the connector module to form an inner space in a state spaced apart from the insulating block by a predetermined distance, each of which is fastened with the insulating block,
Intermediate heat system for construction, characterized in that the outer wall and the inner wall are formed around the insulating block through the concrete poured into the interior space.
The method according to claim 1,
The connector module,
A connector constituting the body of the connector module, and receiving grooves formed at both ends thereof; And
It includes a flat tie formed long and flat in the longitudinal direction in which one end is inserted into the receiving groove,
The euro form,
While being stably fastened through the other end of the flat tie and the wedge pin exposed to the outside,
The connector,
The lower end is inserted into the upper surface of the first insulating block, the upper end is inserted into the lower surface of the second insulating block adjacent immediately above the first insulating block, and the first insulating block and the second insulating block So that it can be tightened more tightly,
Interruption heat system for construction, characterized in that the insulating block does not behave randomly even when the side pressure generated by the concrete is poured.

The method according to claim 1,
The connector module,
A connector constituting the body of the connector module, an accommodating groove being formed at an end extending inward, and a bolt accommodating port formed at an end extending outward;
A first flat tie formed long and flat in a longitudinal direction in which one end is inserted into the receiving groove;
A connection socket having one end bolted to the bolt receiving port; And
The connection socket and a second flat tie that is formed in a long and flat direction in the longitudinal direction to which one end is inserted,
The connection socket,
It is formed of a synthetic resin material having a set strength and a low thermal conductivity.
Interruption heat system for construction, characterized in that it is possible to additionally add a thermal bridge blocking effect through the connector module.
The method according to claim 2 or claim 3,
The wall module.
To further include a reinforcing bar reinforced in a pattern and shape set in the inner space formed between the heat insulating block and the flow path form,
Interruption heat system for construction, characterized in that it can reinforce the structural safety of the building.
The method according to claim 1,
The basic module,
A cast frame formed of a structural tree according to a plane set on the upper surface of the ground;
A cast-in-place layer formed by pouring concrete into the inside of the cast-iron frame;
An outer insulating plate formed to be spaced inward by a predetermined distance from the outer edge of the caster;
A foundation insulating plate formed in close contact with the inside of the outer insulating plate;
A basic reinforcing bar reinforced in a pattern and shape set on the upper portion of the foundation insulating plate; And
Including the concrete for the foundation poured in the space formed by the heat insulating block and the base insulation plate,
The outer insulating plate,
Through the insulating material connecting pin, the lower end of which is inserted into the receiving groove formed in the longitudinal direction on the upper surface,
The lower surface of the heat insulating block, which is located at the bottom end of the wall module, is tightly fastened,
Interruption heat system for construction, characterized in that the insulating block does not behave randomly even when the side pressure generated by the concrete is poured.
The method according to claim 1,
The roof module,
Sleeve form, which is a formwork for forming a roof when pouring concrete;
A memo formed at a set position on the top surface of the slab form; And
Including the euro form attached to the upper surface of the memo diagram,
A medium heat system for construction, characterized in that it can form a parapet wall.
A method for constructing a suspended heat for building using one of the suspended heat systems for building described in claims 1 to 6,
A foundation module construction step of forming a foundation of the building on the set ground;
A wall module construction step of forming a frame for forming a vertical wall on top of the basic module formed through the basic module construction step;
A roof module construction step of forming a frame for forming a roof layer on an upper portion of the frame for forming a vertical wall formed through the wall module construction step; And
Concrete is poured into the space inside the frame formed through the wall module construction step and the roof module construction step, and after the cast-in concrete is cured, the euroform forming the frame is removed and the insulation of the opening is reinforced. Construction method of suspended heat system for construction, characterized in that it comprises a concrete pouring and insulation reinforcement steps.
The method according to claim 7,
The basic module construction step,
A cast-iron frame construction step of forming a cast-iron frame on the set ground surface;
A cast-in-place layer construction step of pouring cast-in concrete along the cast-iron frame to form a cast-in-place layer and flattening the cast-in-place layer;
The outer insulating plate forming an outer index plate by attaching an insulating material having a certain thickness to the upper surface of the cast-in-place layer and the foundation insulating plate forming a separate index plate inside the outer insulating plate at the same height as the outer insulating plate, respectively, the casting cast layer Construction step of the basic insulation plate attached to;
A lower end wall construction step of positioning the insulation block in the longitudinal direction along the upper surface of the outer insulation plate;
A basic reinforcing bar reinforcement step of reinforcing a basic reinforcing bar in a space formed through the bottom insulating wall formed through the insulating block and the foundation insulating plate; And
Including the foundation concrete pouring step of pouring the concrete for forming the foundation structure in the space formed through the base insulation plate and the bottom end wall formed through the insulating block,
The base insulation plate construction step,
After forming the guide groove in the longitudinal direction on the upper surface of the outer insulation plate, further comprising the step of inserting a heat insulating material connecting pin,
The bottom wall construction step,
When positioning the insulating block in the longitudinal direction on the upper surface of the outer insulating plate, by being fastened with the insulating material connecting pin in the connecting pin receiving groove formed on the lower surface of the insulating block,
Method for constructing a discontinued heat system for building, characterized in that the insulating block forming the lowermost wall is supported so that it does not deviate or move randomly at a set position by concrete side pressure that may occur in the concrete pouring and insulation reinforcement step.
The method according to claim 7,
The wall module construction method,
A wall assembly construction step of sequentially stacking insulating blocks in a length direction and a height direction along the set upper surface of the foundation module;
A flat tie construction step of inserting and receiving a flat tie into a connector exposed inside the stacked insulating block;
An inner wall reinforcing bar step of reinforcing the reinforcing bars for the inner wall in a pattern and shape set as a guide for the flat tie protruding toward the inside of the heat insulating block;
Including the euroform construction step of fastening the euroform while maintaining a predetermined distance with one end of the flat tie formed protruding inward,
The flat tie,
Construction method of a medium-sized heat system for construction, characterized in that it is possible to flatten the neighboring Euroform through a wedge pin that is inserted into the center of the four neighboring Euroforms where the corners are in contact with each other and is fastened to the insertion groove of the flat tie and the round tie. .

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