KR101173688B1 - Modular unit system with floor heating plate - Google Patents

Abstract

PURPOSE: A modular unit system using a lightweight composite bottom plate integrated with a heating pipeline is provided to prevent vibration and impact sounds from being directly transferred to a modular unit. CONSTITUTION: A modular unit system using a lightweight composite bottom plate integrated with a heating pipeline is formed by horizontally or vertically connecting modular units. Each modular unit is formed by assembling columns, beams(130), and a bottom plate. The bottom plate is composed of a lightweight composite bottom plate formed by concrete(20), joists(11), and a hot water panel(70). The bottoms are buried in the concrete, and the tops are exposed to the outside. The hot water panel is formed on the tops of the joists.

Description

Modular unit system with light composite floor plate integrated with heating piping {Modular unit system with floor heating plate}

The present invention relates to a modular unit system using a light-weight composite bottom plate integrated with heating piping, and more specifically, after fixing bolts in advance on a column, a connection plate is inserted between an upper end and a lower end of a column of an adjacent modular unit. By connecting the lower and lower pillars, the connecting plate connects all the pillars of the adjacent modular unit to form the vertical structure of the modular unit and at the same time serves as a horizontal connection. The present invention relates to a modular unit system using a lightweight composite floor plate integrated with a heating pipe that can be reduced in weight while minimizing the thickness of the floor plate and can be integrated with the beam to prevent the beam from sagging.

"Steel Frame Modular Unit Housing" is a technology that systemizes high-quality housing to ensure the recycling of resources, while securing a certain quality and supplying it to many customers. To this end, high-fidelity box-type steel frame is produced at the factory, and the technology requires a technology that can be completed in a short period of time with a minimum process.

The steel frame unit modular housing is a factory production member, so the loss is low and it is the best housing production method for reuse and recycling.

However, in the related art, the columns and the beams are joined by a joining method such as brackets and welding. This is not only the stress transmission is unclear, but also problems such as heat deformation due to the increase in the amount of steel plates, bolts and welds, and the resulting problems of construction assembly error and the performance of the joint portion, it was difficult to high-rise.

Background art of the present invention is a patent registration No. 1031299 "A joining structure and a method of the unit unit module for the integral behavior of the modular building" (Patent Document 1).

In the background art, in order to solve the above problems, as shown in Figure 1, the unit unit module 100a manufactured by assembling the pillar 110a, the floor beam 120a, the ceiling beam 130a with a channel or a square tube. In the modular building to be built while connecting the vertically or vertically stacked, the unit unit module (100a) is made so that the upper and lower ends of the column is lower than the floor beam (120a) and ceiling beams (130a), vertically or horizontally By being installed adjacent to each other, adjacent unit unit modules 100a are installed while forming horizontal gaps in the pillars, and the connecting shear plates 210a are fitted to the horizontal gaps to be tightly connected to the pillars of the unit unit modules 100a. The joint structure of the unit unit module and its method are proposed for the integral behavior of modular buildings.

However, the background art is to be formed in the upper beams and lower beams of the column respectively than the ceiling beams to form a horizontal gap, and the upper beams and the lower beams are made in contact with the horizontal gap to form a connecting shear plate of the bottom plate There was a problem that the shock vibration sound generated in the upper portion is transmitted to the lower portion through the beam.

Another background technology that is the background of the present invention is Patent Registration No. 0947297 "Building modular unit in which floor concrete is integrally formed" (Patent Document 2).

In the background art, as shown in FIG. 2, the pillars, ceiling beams, and floor beams are assembled to form a skeleton of the modular unit in the form of no connector, and then the modular unit is placed on the formwork support plate and the formwork plate 220 from the bottom therein. And the slab heat insulating material 230 is sequentially loaded and then installed the reinforcing steel 240, and then cast concrete 260 proposes a modular unit formed integrally with the slab insulation material and the bottom concrete at the bottom.

However, in the background art, the slab insulation material and the floor concrete are integrally formed, but the reinforcement amount and the amount of concrete used are excessive, thereby increasing the weight of the unit and increasing the transportation cost and causing the lifting problem. Since the construction of the floor must be made in the field, the manufacturing process of the bottom plate is complicated, and the air is increased and the cost is increased.

In addition, since the bottom plate is not lightened, the beam and the bottom plate are not integrated, and a separate connector is not formed, the bottom plate and the beam and the column are not easily joined, and the bottom plate and the beam and the column are not easily joined. There is a problem in that it is impossible to smoothly transfer the load of the modular unit even when the modular units are coupled to each other because they are not tightly integrated.

Patent Registration No. 1031299 Patent Registration No. 0947297

The present invention is to solve the above problems, by fixing the bolt in advance on the column upper part by inserting the connecting plate between the pillars of the adjacent modular unit to fasten the upper column and the lower column, the connection plate is adjacent The modular unit system uses a lightweight composite floor plate with integrated heating piping that connects the pillars of the modular unit to form a vertical connection and also serves as a horizontal connection. It is an object of the present invention to provide a modular unit system using a light-weight synthetic bottom plate integrated with a heating pipe that is easy to apply, easy to assemble and disassemble, and is easy to recycle.

In addition, by using a lightweight composite floor plate with integrated heating pipes between the bent beams, it is possible to reduce air production and manufacturing costs by manufacturing ondol floor factories, and to increase floors by lightening floor plates, and to secure noise / vibration performance. (Shock impact sound) It is an object of the present invention to provide a modular unit system using a lightweight composite floor plate integrated with a heating pipe, which can be reduced and is advantageous for securing fire resistance and increasing lateral stiffness.

In addition, the lower beam of the modular unit coupled vertically to the upper beam can be configured not to directly contact the impact to minimize the generation of impact vibration noise, and the structural safety of the overall frame of the modular unit is increased by the integral behavior of the lower beam and the bottom plate It is an object of the present invention to provide a modular unit system using a light-weight composite bottom plate integrated heating piping.

The present invention is a modular unit system for connecting a modular unit produced by assembling the column, beam, and bottom plate horizontally or vertically, the pillar is a bolt configured in the upper vertical portion, the fastening hole is formed at the lower end and fastened to the side The sphere is formed through the through, the bottom plate is formed in the bottom portion of the concrete formed of a floating bottom structure; The joist is formed so that only the lower portion is embedded in the concrete stud at a predetermined interval; A hot water panel configured at the top of the joist and configured to form a hollow layer between the concrete; a heating pipe integrated light weight composite bottom plate formed of a fastening hole corresponding to the bolt on the column is formed and the adjacent modular unit The purpose of the present invention is to provide a modular unit system using a heating composite integrated lightweight composite floor plate, comprising connecting and connecting a connection plate having the same size as the sum of the cross sections of the pillars between the upper pillar and the lower pillar of an adjacent modular unit.

The first embodiment of the heating pipe integrated lightweight composite floor plate of the present invention is configured between the beam and concrete formed in the bottom structure by forming a space portion at the bottom; The joist is formed so that only the lower portion is embedded in the concrete stud at a predetermined interval; It is intended to provide a heating pipe integrated lightweight composite floor plate formed of; a hot water panel configured on the top of the joist and configured to form a hollow layer between concrete.

Another embodiment of the first embodiment is to provide a light-weight composite bottom plate integrated with a heating pipe in which the heat insulating material is formed in the hollow layer.

Another embodiment of the first embodiment is to provide a hollow composite layer heating composite integrated lightweight composite floor plate is composed of a heat insulating material and the top of the heat insulating material.

The second embodiment of the heating pipe-integrated lightweight composite floor plate of the present invention is a Jang Sun consisting of a predetermined interval between the beam; Concrete constructed on the upper joists; Excel pipe configured on the concrete; An object of the present invention is to provide a light-weight composite bottom plate integrated with a heating pipe composed of a finishing mortar configured for finishing on an upper part of an Excel pipe.

Another embodiment of the second embodiment is to provide a heating composite integrated lightweight composite floor plate composed of a finishing mortar concrete is composed of only the upper portion of the joist is formed in the form of floating floor.

The third embodiment of the heating pipe integrated lightweight composite floor plate of the present invention, in turn, between the heat insulating material for insulation; Wire mesh installed at intervals from the insulation; Concrete configured on top of the wire mesh; Excel pipe configured on the concrete; An object of the present invention is to provide a light-weight composite bottom plate integrated with a heating pipe composed of a finishing mortar configured for finishing on an upper part of an Excel pipe.

Fourth embodiment of the heating pipe integrated lightweight composite floor plate of the present invention comprises a joist composed of a predetermined interval between the beam; The lower part of the joist is to cast the upper part of the joist so that the empty space is formed and the concrete is formed so that the joist is embedded in the stud form; A heat insulating part composed of a heat insulating material and silver foil artyron; Excel pipe configured on the concrete; An object of the present invention is to provide a light-weight composite bottom plate integrated with a heating pipe composed of a finishing mortar configured for finishing on an upper part of an Excel pipe.

The fifth embodiment of the heating pipe integrated lightweight composite floor plate of the present invention comprises a joist composed of a predetermined interval between the beam; OSS non-plywood is configured on the top of the joist; Insulation material, a heat-panel formed inside the hot water pipe, the heat insulation portion consisting of silver foil artyron; An object of the present invention is to provide a light-weight composite floor plate integrated with a heating pipe composed of a fiber-reinforced cement board formed on the heat insulation part.

The sixth embodiment of the heating pipe integrated lightweight composite floor plate of the present invention is configured between the beam, consisting of a heat insulating material composed between the flat deck and the flat deck vertically configured at regular intervals from the bottom, the heat insulating space at the bottom A heat insulating part configured of a floating bottom structure to form a part; Concrete configured on top of the insulation; An object of the present invention is to provide a light-weight composite floor plate integrated with a heating pipe composed of hot water panels formed on concrete.

Modular unit system using a heating composite integrated lightweight composite bottom plate according to the present invention is fixed to the upper part of the column at the time of coupling the modular units in advance, and then insert the connecting plate between the pillars of the adjacent modular unit and the upper column and By fastening the lower pillar, the connecting plate connects the pillars of the adjacent modular unit to form a vertical connection of the modular unit and also serves as a horizontal connection at the same time, and is easy to be fastened by an open fastener. In addition, it is possible to combine the pillars of the adjacent modular unit by configuring to ensure integral behavior, so that it is possible to smoothly transfer the load of the modular unit, which is suitable for the high-rise structure, and the upper beam of the lower modular unit and the upper of the modular unit Since the lower beams are not in contact with each other, the vibration shock sound There is an effect that is not directly transmitted to the modular unit unit.

In addition, by using a lightweight composite floor plate with integrated heating piping between the bendable beams, it is possible to reduce the air shortening and manufacturing cost by manufacturing the ondol layer factory. It is possible to solve the problem, and to reduce the noise between the floors (weight impact sound) by securing shock / vibration performance, and to secure fire resistance, increase lateral stiffness and high layer, and to behave integrally with the beam to prevent the drooping of the beam. It has a useful effect.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
1 is a detailed view showing the installation details of the laminated unit unit modules in the bonding between the unit unit modules of the conventional modular building;
2 is a cross-sectional view of the floor concrete of a building modular unit in which conventional floor concrete is integrally formed;
Figure 3 is a perspective view of a modular unit using a light-weight composite bottom plate integrated heating piping of the present invention,
Figure 4 is a perspective view showing a coupling state between the modular unit of the modular unit system using the heating pipe integrated lightweight composite bottom plate of the present invention,
5 is a perspective view showing an embodiment of the coupling between the modular units of the present invention,
6 is an application state diagram and a cross-sectional view of the first embodiment of the heating pipe integrated lightweight composite floor plate 140 of the present invention;
7 is a state diagram and a cross-sectional view of another embodiment of FIG.
8 is a state diagram and a cross-sectional view of another embodiment of FIG.
9 is an application state diagram and a cross-sectional view of a second embodiment of a heating composite integrated lightweight composite floor plate 140 of the present invention;
10 is a state diagram and a cross-sectional view of another embodiment of FIG.
11 is an application state diagram and a cross-sectional view of a third embodiment of a heating composite integrated lightweight composite floor plate 140 of the present invention;
12 is an application state diagram and a cross-sectional view of a fourth embodiment of the integrated heating piping integrated lightweight composite floor plate 140 of the present invention;
13 is a state diagram and a cross-sectional view of the fifth embodiment of the heating pipe integrated lightweight composite floor plate 140 of the present invention;
14 is a state diagram and a cross-sectional view of the sixth embodiment of the heating composite integrated lightweight composite floor plate 140 of the present invention.
Figure 15 is a perspective view showing an embodiment of a modular unit system using a light-weight composite bottom plate integrated heating piping of the present invention.

In the following the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the embodiments presented are exemplary for a clear understanding of the present invention is not limited thereto.

Hereinafter, the technical structure of the present invention will be described in detail with reference to the preferred embodiments.

As shown in FIG. 3, the modular unit system according to the present invention includes a pillar 120, a heating pipe-integrated lightweight composite floor plate 140, and a beam unit 130. It is a system to combine horizontally.

As shown in FIG. 4, after the bolts 121 are vertically formed on the upper ends of the pillars 130 of each modular unit, the connection unit 170 is vertically stacked, and the modular unit 100 adjacent to the modular unit 100 is vertically stacked. The modular unit system is inserted between the pillars 120 to fasten the pillars of adjacent modular units in a horizontal and vertical direction.

The modular unit 100 according to the present invention includes a pillar 120, a bottom plate 140, and a beam 130.

The pillar 120 is made of a square steel pipe and functions as a vertical member in the modular unit 100. The beam 130 has a bent cross section and is fastened by welding or bolting to the side of the pillar 120.

The pillar 120 has a bolt 121 formed vertically upward on the upper end, a fastening hole 122 is formed on the lower end, and a fastener 123 is formed on the side thereof.

The number of bolts 121 configured vertically upward may be one or more, and may vary depending on the construction conditions.

A fastening hole 122 is formed at the lower end, which combines the lower end of the upper modular unit column and the upper end of the lower modular unit column when the modular units are vertically coupled to each other, where the bolt 121 is coupled.

Accordingly, the fastening hole 122 is formed in the same number at the position corresponding to the bolt 121.

The fastener 123 is for the operator to facilitate the fastening at the time of coupling the lower end of the upper modular unit column and the upper end of the lower modular unit column, if the fastener 123 is not formed, fixing the bolt 123 Since it is difficult to configure the side of the beam 130 is coupled to the side of the fastening hole 122 is formed. The side that is not coupled to the beam is a place where the beams are coupled to each other because the other modular unit is adjacent to the coupling.

As shown in FIGS. 5A and 5B, when the modular unit 100 configured as described above is vertically and horizontally coupled, a fastening hole 171 corresponding to the bolt 121 of the upper part of the pillar 120 is formed and adjacent thereto. The connecting plate 170 having the same size as the sum of the cross sections of the pillars of the modular unit is fastened by being configured between the upper pillar and the lower pillar of the adjacent modular unit.

Forming the connecting plate 170 in the same size as the cross-section of the adjacent modular unit column is because the modular unit to be joined is composed of up to four upper four lower four combinations and may be composed of a combination of less than Adjust the size of the connecting plate according to the number of modular units.

For example, if the modular unit to be combined consists of two components, the upper two and the lower, it is to form a connecting plate in the size of the cross-section of the two pillars.

In FIG. 4, the connecting plate 170 is illustrated in the same cross-sectional size as one pillar for convenience, but as shown in FIG. 5A, in the case of a combination of two adjacent pillars, the size of the connecting plate 170 is the area of the two pillars. The same as the sum of, and as shown in Figure 5b, in the case of a combination of four adjacent pillars is the size of the connection plate 170 is configured to be equal to the sum of the area of the four pillars.

Modular unit 100 of the present invention is configured to complete a variety of heating pipe integrated lightweight composite floor plate 140 between the lower beams.

Hereinafter, various embodiments of the heating pipe integrated lightweight composite floor plate 140 according to the present invention will be described in detail.

Heating pipe integrated lightweight composite floor plate 140 according to the present invention is basically configured between the bent beam 130 using a beam 130 having a bent cross-section, integral with the beam 130, heating pipe The integrated lightweight composite bottom plate 140 and the beam 130 to be integrally behaved.

The first embodiment of the heating pipe integrated lightweight composite floor plate 140 of the present invention is configured between the beam 130 and the concrete 20 is formed in a floating bottom structure by forming an insulating space portion (30c) in the lower portion; Joist (11) is formed so that only the lower portion in the concrete 20 at a predetermined interval in the stud shape and the upper portion is exposed; The hot water panel 70 is configured on the joist 11 and configured to form a hollow layer 20b between the concrete 20.

Concrete 20 is formed between the beams 130 and is formed in a floating bottom structure by forming a space portion (20a) in the lower portion.

The concrete 20 is configured to form a floating floor structure having a predetermined space at the bottom, for this purpose is formed by forming a formwork between the beams 130 and pouring concrete. At this time, the joist 11 is formed in the stud form so that only the lower part is embedded in the concrete 20 at a predetermined interval, and the upper part is completed by installing the joist together when installing the formwork for concrete placing to expose the completed.

The hot water panel 70 is formed on the upper part by using the joist 11 exposed on the concrete 20 as a support. Since the joist 11 is exposed to the upper part of the concrete, the hot water panel 70 and the concrete 20 The hollow layer 20b is formed between the two layers, and the hollow layer 20b is formed in order to minimize adiabatic effect and impact vibration sound.

The hot water panel 70 is for heating, and since the hot water panel 70 formed to a predetermined standard is laid on the upper part of the joist 11, the construction is very easy, and only the necessary place can be configured for split heating.

The hot water panel 70 is a ready-made product and is commercialized in various kinds and standards.

Another embodiment of the first embodiment of the heating pipe integrated lightweight composite floor plate 140 of the present invention is characterized in that the heat insulating material (30a) is configured in the hollow layer (20b) of the bottom plate.

Although the hollow layer 20b itself may exhibit a heat insulating effect, in order to prevent heat conduction leaking to the lower portion of the hot water panel 70 and to double the heat insulating effect, the heat insulating material 30a is further configured.

Insulation material (30a) is configured for insulation and sound absorption, EPS insulation material (EPS; Expanded Polystyrene), glass wool (Glass Wool), rock wool (rock wool, Rock Wool), etc. are mainly used, various insulation materials can be used depending on the application have.

Another embodiment of the first embodiment is characterized in that the hollow layer (20b) of the bottom plate is characterized in that the concrete (20c) is configured on top of the heat insulating material (30a) and the heat insulating material (30a).

The heat insulating material 30a and the concrete 20c are formed simultaneously in the hollow layer 20b, and it is comprised in order to prevent damage of the hot water panel 70 and the heat insulating material 30a from the impact of the upper part, and to improve fire resistance performance.

The second embodiment of the heating pipe integrated lightweight composite floor plate 140 of the present invention is a joist (10) consisting of a predetermined interval between the beam 130; Concrete 20 that is poured over the joist 10; Excel pipe 40 is configured on the concrete 20; Characterized in that formed by; finish mortar (50) configured for finishing on the top of the Excel pipe (40).

The joist 10 is configured to be arranged at regular intervals between the beams 130.

The joists 10 are configured to face each other to form a closed cross-section of the interior, or use a square tube, and to form a hollow 10a through the empty center.

Since the concrete 20 is constructed as much as the dance height of the beam 130, if the joist 10 does not form a closed cross-section, its own weight may be increased, thereby forming the joist 10 of the closed cross-section to use the concrete 20. To reduce the weight of the self, and to form a hollow (10a) to prevent vibration is transmitted to the floor impact sound can be reduced.

Concrete 20 is configured on the upper portion of the joist 10 arranged at a predetermined interval so that the joist 20 acts integrally with the concrete while acting as a reinforcing bar.

Concrete 20 should be configured about 150mm in consideration of the dance of the beam 130, the thickness of the concrete 20 is advantageous to ensure the fire resistance performance.

Excel pipe 40 is configured on the concrete 20.

Excel pipe 40 is a heating pipe, is configured to distribute evenly at a predetermined interval on the top of the concrete (20).

Finishing mortar 50 is configured for finishing on the top of the Excel pipe 40.

In addition, another embodiment of the second embodiment of the heating pipe integrated lightweight composite floor plate 140 of the present invention is the concrete 20 in the form of a floating floor is placed only in the upper portion of the bottom and left empty based on the top surface of the joist 10 It is characterized in that the configuration.

Based on the top surface of the joist 10, the lower part is left empty, and the concrete 20 is formed only on the upper part.

Forming the floating floor structure as described above is to make the joist 10 supports the bottom of the concrete 20 in order to reduce the floor impact sound, the space portion 10b between the joist 10 and the joist 10 It is to be formed, the concrete 20 is to be floating by the joist 10.

Therefore, even if the impact force acts on the upper portion of the concrete 20, since the vibration is hardly transmitted to the lower portion by the buffering action of the space portion 10b, it is possible to prevent the transmission of the impact sound.

The third embodiment of the heating pipe integrated lightweight composite floor plate 140 of the present invention is a heat insulating material 12 for heat insulation; A wire mesh 13 disposed on the upper portion at a distance from the heat insulating material 12; Concrete 20 is placed on top of the heat insulating material 12 to include a wire mesh (13); Excel pipe 40 is configured on the concrete 20; Characterized in that formed by; finish mortar (50) configured for finishing on the top of the Excel pipe (40).

Insulation material 12 is configured for insulation and sound absorption, EPS insulation material (EPS; Expanded Polystyrene), glass wool (Glass Wool), rock wool (rock wool, Rock Wool), etc. are mainly used, various insulation materials can be used depending on the application have.

EPS (Expanded Polystyrene) is mainly used for outer insulation, which prevents heat from being transferred to the slab.

Glass wool is a glass fiber, with a fiber diameter of about 5 to 10㎛, broken in the lateral direction, and does not affect the diameter.Even when entering the respirator, it is easily soluble in the human body because of its amorphous structure, which is different from the crystalline structure. Exhaust out of the body. In addition, it is excellent in non-combustibility, it is resistant to fire and can be used in various forms according to the building purpose.

Rock wool is an artificial mineral fiber manufactured at the factory using rock as a raw material, and is an insulating material having effects such as sound absorption and heat insulation.

The wire mesh 13 is configured on the top of the heat insulating material 12 at intervals from the heat insulating material 12, and casts concrete 20 on top of the heat insulating material 12 so that the wire mesh 13 takes the role of reinforcing steel. do. In addition, the wire mesh 13 also serves to prevent the phenomenon of the filling of the heat insulating material 12, the construction of the wire mesh 13 after the construction by pouring concrete and curing the Excel pipe 40, or wire mesh 13 After fixing the excel pipe 40 with a connecting strap on the upper part may be formed by pouring concrete between the excel pipe and the heat insulating material.

Excel pipe 40 is configured on the concrete 20.

Excel pipe 40 is a heating pipe, is configured to distribute evenly at a predetermined interval on the top of the concrete (20).

Finishing mortar 50 is configured for finishing on the top of the Excel pipe 40.

Fourth embodiment of the heating pipe integrated lightweight composite floor plate 140 of the present invention comprises a joist (11) configured at regular intervals between the beam (130); The lower part of the joist 11 is concrete 20 formed so that the joist 11 is embedded in the stud form by pouring only the upper part of the joist 11 to form the space portion 11a; A heat insulating part 30 formed on the concrete 20 and composed of a heat insulating material 31 and a silver foil artiron 33; Excel pipe 40 is configured on the concrete 20; Characterized in that consisting of; finishing mortar 50 is configured for finishing on the top of the Excel pipe (40).

The joist 11 is configured to be disposed at regular intervals between the beams 130. The joist 11 serves to support an upper structure such as concrete 20, and the space portion 11a is formed by pouring concrete 20 only on the upper portion of the joist 11 so that the lower part of the joist 11 is empty. And the joist 11 is formed to be embedded in the stud form so that the heating pipe integrated lightweight composite bottom plate 140 and the beam 130 behave integrally.

As described above, since the joist 11 is configured in the stud shape and behaves integrally with the concrete 20, and the space portion 11a is formed to have a floating bottom structure, the impact force acts on the upper portion of the concrete 20. Even if the vibration is hardly transmitted to the lower portion by the buffering action of the space (11a) it can prevent the transmission of the impact sound.

In addition, by preventing the concrete 20 is configured as the dance height of the beam 130, it is possible to reduce the amount of use of the concrete 20 to reduce its own weight.

The heat insulation part 30 is comprised from the heat insulation material 31 and the silver foil artiron 33. As shown in FIG.

Insulation material 31 is configured for insulation and sound absorption, EPS insulation material (EPS; Expanded Polystyrene), glass wool (Glass Wool), rock wool (rock wool, Rock Wool), etc. are mainly used, various insulation materials can be used depending on the application have.

The silver foil artiron 33 is further configured on top of the heat insulator 31.

Atiron is a cross-linked polyethylene foam with independent bubble structure, which has excellent thermal insulation and low thermal conductivity.As it is a non-absorbent material, it does not lose its thermal insulation performance even after a long time. Condensation is unlikely to occur, and condensation does not occur in the bubbles as independent bubbles such as urethane and glass wool of continuous bubbles. In addition, since Atyrone is a semi-rigid blowing agent, it has excellent buffering properties and reduces vibration.

Silver foil Atyron is coated with silver foil on top of the artyron, which is configured for heat reflection. That is, since the Excel pipe 40 is configured on the upper side, the heat reflection and heat insulation are effective.

Excel pipe 40 is configured on the concrete 20.

Excel pipe 40 is a heating pipe, is configured to distribute evenly at a predetermined interval on the top of the concrete (20).

Finishing mortar 50 is configured for finishing on the top of the Excel pipe 40.

Preferably, the joist 11 is configured at the lower end in consideration of the dance of the beam 130, and the concrete 20 is engaged with the joist 11 to form a thickness of about 55 to 65 mm to optimize the allowable stress. Consists of, the heat insulating material 31 is 25 ~ 35 mm, silver foil artiron 33 is 2 ~ 4 mm, the Excel pipe 40, the finishing mortar 50 is composed of a thickness of 35 ~ 45 mm on the top.

The fifth embodiment of the heating pipe integrated lightweight composite floor plate 140 of the present invention comprises a joist (11) configured at regular intervals between the beams (130); An OS non-plywood 21 formed at an upper portion of the joist 11; The heat insulating part 30 is configured in the upper portion of the OSP plywood 21, the heat insulating member 31, the P panel 32 is formed inside the hot water pipe, and the silver foil artiron 33; Fiber-reinforced cement board 60 is configured on the heat insulating portion 30; is composed of a dry hot water ondol system to form a floating floor structure.

The joist 11 is configured at regular intervals between the beams 130. The joist 11 serves to support the upper structure of the OSS plywood 21, the heat insulating part 30, and the fiber-reinforced cement board 60, that is, the space between the joist 11 and the joist 11 The part 11b is formed.

The OSS plywood 21 is configured to facilitate the fabrication of the floor, and the OSS plywood 21 may be easily placed on the top of the joist 11 to form a diaphragm and form a floating bottom structure.

OSB (Oriented Strand Board) is a wood processing panel manufactured by arranging rectangular thin pieces of wood stacked at right angles to each other. It is often used as a cover for walls, floors, and roofs. It maintains hardness and is resistant to moisture because it uses phenol formaldehyde resin adhesive, and can be used for external use.

The OSS plywood 21 is formed on the joist 11 so that the space 11b is formed between the joist 11 and the joist 11, and a floating bottom structure is generated.

Forming the floated floor structure as described above, so that the joist 11 supports the bottom of the OSB plywood 21 in order to reduce the floor impact sound, the space portion 11b between the joist 11 and the joist 11 ), And the OSB plywood 21 is floated by the joist 11.

Therefore, even when the impact force acts on the OSB plywood 21 and the structure of the upper portion, the vibration is hardly transmitted to the lower portion by the buffering action of the space portion 11b, thereby preventing the transmission of the impact sound.

The heat insulating part 30 is configured for heat insulating, and the heat insulating material 31, the piezoelectric panel 32, and the silver foil artiron 33 are sequentially formed from the bottom.

Insulation material 31 is configured for insulation and sound absorption, EPS insulation material (EPS; Expanded Polystyrene), glass wool (Glass Wool), rock wool (rock wool, Rock Wool), etc. are mainly used, various insulation materials can be used depending on the application have.

The piezoelectric panel 32 is configured above the heat insulating material 31, and a hot water pipe is formed inside the piezoelectric panel 32.

The PE panel is formed by a heat fusion method in which the PE resin is sandwiched between two PE resins to form a hot water pipe (not shown) with a concave-convex structure like a cardboard inlay, and applied by applying heat.

The silver foil artiron 33 is further configured on the upper part of the piezoelectric panel 32.

Atiron is a cross-linked polyethylene foam with independent bubble structure, which has excellent thermal insulation and low thermal conductivity.As it is a non-absorbent material, it does not lose its thermal insulation performance even after a long time. Condensation is unlikely to occur, and condensation does not occur in the bubbles as independent bubbles such as urethane and glass wool of continuous bubbles. In addition, since Atyrone is a semi-rigid blowing agent, it has excellent buffering properties and reduces vibration.

Fiber-reinforced cement board 60 is configured on the heat insulating portion 30 is used as a finishing material.

CRC board (Cellulose fiber Reinforced Cement) is a product produced by curing natural pulp, secant, silica sand, additives, etc. with water and then curing it. It has excellent water resistance, fire resistance, and sound insulation. .

The sixth embodiment of the heating pipe integrated lightweight composite floor plate 140 of the present invention is a flat deck (35) configured vertically at regular intervals between the beams, and a heat insulating material (36) composed between the flat deck (35) An insulating part 30b made of a floating floor structure to form an insulating space part 30c at a lower portion thereof; Concrete 20 is configured on the heat insulating portion (30b); It is formed of; hot water panel 70 is configured on the concrete 20.

The heat insulating portion 30b is configured to form a floating bottom structure by forming a heat insulating space portion 30c at the bottom.

The heat insulation part 30b forms a flat deck 35 at regular intervals between the beams 130, and forms a heat insulating material 36 between the flat decks 35, and the flat deck 35 at regular intervals. Configured to serve as a support.

Insulation material 36 is configured for insulation and sound absorption, EPS insulation material (EPS; Expanded Polystyrene), glass wool (Glass Wool), rock wool (rock wool, Rock Wool) is mainly used, and various insulation materials can be used depending on the purpose have.

Concrete 20 is configured on the upper portion of the heat insulating portion 30b for the protection and support of the heat insulating portion 30b formed in the lower portion.

The hot water panel 70 is configured on the concrete 20 to finish.

The hot water panel 70 is for heating, and since the hot water panel 70 formed to a predetermined standard is laid on the upper part of the joist 11, the construction is very easy, and only the necessary place can be configured for split heating.

The hot water panel 70 is a ready-made product and is commercialized in various kinds and standards.

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

10: joist 11: joist
11a, 20a: space part 12, 30a, 31: heat insulating material
13: wire mesh 20, 20c: concrete
20b: hollow layer 21: OBS non-plywood
30, 30b: heat insulation part 30c: heat insulation space part
32: pie panel 33: silver foil artyron
35: flat deck 36: insulation
40: Excel Pipe 50: Finish mortar
70: hot water panel 60: fiber reinforced cement board
100: modular unit 120: pillar
121: bolt 122: fastening hole
123: fastener 130: beam
140: Lightweight composite flooring plate with integrated heating piping
170: connection plate 171 fastening hole

Claims (9)

In the modular unit system for horizontally or vertically connecting the modular unit 100 manufactured by assembling the column 120, the beam 130, and the bottom plate 140,
The pillar 120 has a bolt 121 formed vertically upward on the upper end, a fastening hole 122 is formed on the lower end, and a fastener 123 is formed on the side thereof.
The bottom plate is a concrete 20 formed in a floating bottom structure by forming a space portion 20a at the bottom; Joist (11) is formed so as to be embedded in the stud form only in the concrete 20 at a predetermined interval; Consists of a heating pipe integrated lightweight composite floor plate 140 formed of an upper portion of the joist (11) and the hot water panel 70 is configured to form a hollow layer 20b between the concrete 20,
A fastening hole 171 corresponding to the bolt 121 on the upper part of the pillar 120 is formed, and the connecting plate 170 having the same size as the sum of the cross-sections of the pillars of the adjacent modular unit is connected to the upper pillar and the lower part of the adjacent modular unit. Modular unit system using a light-weight composite bottom plate integrated with heating piping, characterized in that the fastening is configured between the pillars. The method of claim 1,
Modular unit system using a heating pipe integrated lightweight composite floor plate, characterized in that the hollow layer (20b) is configured with a heat insulating material (30a). The method of claim 2,
Modular unit system using a heat-integrated lightweight composite floor plate, characterized in that the hollow layer (20b) is characterized in that the concrete (20c) is configured on top of the heat insulating material (30a) and the heat insulating material (30a). delete delete delete In the modular unit system for horizontally or vertically connecting the modular unit 100 manufactured by assembling the column 120, the beam 130, and the bottom plate 140,
The pillar 120 has a bolt 121 formed vertically upward on the upper end, a fastening hole 122 is formed on the lower end, and a fastener 123 is formed on the side thereof.
The bottom plate is a joist (11) configured at regular intervals between the beams (130); The lower part of the joist 11 is concrete 20 formed so that the joist 11 is embedded in the stud form by pouring only the upper part of the joist 11 to form the space portion 11a; A heat insulating part 30 formed on the concrete 20 and composed of a heat insulating material 31 and a silver foil artiron 33; Excel pipe 40 is configured on the heat insulating portion 30; Comprised of a heating mortar integral lightweight composite floor plate 140 formed of a finishing mortar 50 configured to finish on the top of the Excel pipe 40,
A fastening hole 171 corresponding to the bolt 121 on the upper part of the pillar 120 is formed, and the connecting plate 170 having the same size as the sum of the cross-sections of the pillars of the adjacent modular unit is connected to the upper pillar and the lower part of the adjacent modular unit. Modular unit system using a light-weight composite bottom plate integrated with heating piping, characterized in that the fastening is configured between the pillars. In the modular unit system for horizontally or vertically connecting the modular unit 100 manufactured by assembling the column 120, the beam 130, and the bottom plate 140,
The pillar 120 has a bolt 121 formed vertically upward on the upper end, a fastening hole 122 is formed on the lower end, and a fastener 123 is formed on the side thereof.
The bottom plate is a joist (11) configured at regular intervals between the beams (130); An OS non-plywood 21 formed at the top of the joist 11; The heat insulating part 30 is configured in the upper portion of the OSP plywood 21, the heat insulating member 31, the P panel 32 is formed inside the hot water pipe, and the silver foil artiron 33; Fiber reinforced cement board 60 is formed on the heat insulating portion 30; consisting of a heating pipe integrated lightweight composite bottom plate 140 formed of,
A fastening hole 171 corresponding to the bolt 121 on the upper part of the pillar 120 is formed, and the connecting plate 170 having the same size as the sum of the cross-sections of the pillars of the adjacent modular unit is connected to the upper pillar and the lower part of the adjacent modular unit. Modular unit system using a light-weight composite bottom plate integrated with heating piping, characterized in that the fastening is configured between the pillars. In the modular unit system for horizontally or vertically connecting the modular unit 100 manufactured by assembling the column 120, the beam 130, and the bottom plate 140,
The pillar 120 has a bolt 121 formed vertically upward on the upper end, a fastening hole 122 is formed on the lower end, and a fastener 123 is formed on the side thereof.
The bottom plate is composed of a flat deck (35) configured vertically at regular intervals between the beams, and a heat insulating material (36) constituted between the flat deck (35) and the bottom structure to form an insulating space portion (30c) at the bottom Insulation part 30b consisting of; Concrete 20 is configured on the heat insulating portion (30b); It is made of a heating pipe integrated lightweight composite floor plate 140 formed of a hot water panel 70 configured on the concrete 20,
A fastening hole 171 corresponding to the bolt 121 on the upper part of the pillar 120 is formed, and the connecting plate 170 having the same size as the sum of the cross-sections of the pillars of the adjacent modular unit is connected to the upper pillar and the lower part of the adjacent modular unit. Modular unit system using a light-weight composite bottom plate integrated with heating piping, characterized in that the fastening is configured between the pillars.

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