KR200413481Y1 - Heating Piping Pannel Having Many Through-Hole And Korean floor heater system using the same - Google Patents

Abstract

The present invention relates to a pipe panel having a porous compartment structure and a package ondol system to which the pipe panel is applied.

To this end, the pipe panel according to the present invention has a body made of a polypropylene material, and forms an air compartment structure that is a through hole penetrating the body at regular intervals, and the heat medium circulation pipe passes through the upper portion of the body. Concave grooves that are paths are formed.

According to the present invention there is an effect that can provide a package on-dol system that can prevent the noise between floors through the pipe panel forming the air compartment structure, rapid heating is achieved, and can efficiently save energy.

Floor construction, piping panel, ondol, air compartment structure

Description

Tubing panel with porous compartment structure and package ondol system using the same panel {Heating Piping Pannel Having Many Through-Hole And Korean floor heater system using the same}

Figure 1a is a plan view of a pipe panel having a porous compartment structure according to an embodiment of the present invention, Figure 1b is an enlarged view of the corner portion of the pipe panel,

2a to 2c is a view showing a preferred embodiment of the air compartment structure applied to the present invention,

3a is a view for explaining the configuration of a package ondol system to which a piping panel having a porous compartment structure is applied;

3B is a side view of the package ondol system of FIG. 3A;

4 is an exploded perspective view of the package ondol system of FIG. 3A;

5A to 5C are flowcharts illustrating a method of constructing ondol heating using a package ondol system according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

10: magnesium board 20: heat sink

21: concave iron plate 30: heat medium circulation tube

40: porous pipe panel 41: recessed groove portion

42: corner portion 43: air compartment structure

50: aluminum insulation

The present invention relates to a pipe panel having a porous compartment structure and a package ondol system to which the pipe panel is applied. More specifically, the pipe is made of polypropylene, which is easy to process, to be selected as a panel for pipe formation, and grooves are formed on the panel at regular intervals to form an air compartment structure, thereby improving sound insulation and thermal insulation effect. The present invention relates to a package ondol system using a panel and a pipe panel thereof.

Conventionally, the floor construction method of a building can be largely divided into a wet method and a dry method.

First, the wet method constructs a heat-insulating and sound-absorbing member such as styrofoam, foamed polyurethane, or foamed polypropylene material, which is a flammable sound absorbing material or shock absorber, on the existing slab, and forms a lightweight foam concrete layer thereon. It is a construction method of forming a floor structure by piping the mortar layer on it again. Such a wet method has a disadvantage in that the construction period is increased as long as the curing period of the concrete layer, and the cost required in the construction process is too high, such as requiring an expert to accurately match the gradient of the plasterer and the hot water pipe for the plastering. In addition, when leaking or breakage of the hot water pipe during construction, there is a problem that it takes a lot of time and money because the repair work is possible only after breaking the concrete layer.

In addition, this wet method is because the cement is used as a construction material, there is a problem of sick house syndrome and environmental hormones from the cement dock, especially recently, according to the government's proposal to prevent interlayer noise (July 2005 notice). There is a problem that the bottom thickness of the layer should be constructed to 180 mm or more.

In order to solve this problem, the dry process is to install a heat insulating plate on the building slab, install a pipe support plate on it, then pipe the hot water pipe and install a metal top plate on it, or transport the floor structure unit assembled in this configuration to the site as a whole. Follow the method of flooring by assembling each other.

Such a dry method improves problems such as excessive construction cost and the new house syndrome due to the use of cement material, which is pointed out as a problem of the wet method, but the metal plate is usually fixed to the support plate with screws or fixing pins. There was a problem that the bottom finish material is dropped or deformed from the top plate due to deformation caused by the screw falling or bending due to thermal expansion by heating at the time.

On the other hand, research and development on a number of heating construction methods using the ondol panel has been made recently, but until now, such construction methods have problems of production cost and difficult construction.

In order to solve this problem, the present invention selects a panel for pipe formation based on easy processing of polypropylene and forms an air compartment groove at regular intervals on the panel to effectively block interlayer noise. In addition, an object of the present invention is to provide a pipe panel with excellent heat insulation effect.

In addition, it is an object of the present invention to provide a package ondol system that anyone can easily and simply construct the ondol heating by using the pipe panel.

An object of the present invention, in the pipe panel applied to the floor construction of the building, the body of the pipe panel is made of a polypropylene material, and forms an air compartment structure which is a through hole penetrating the body at regular intervals and In addition, the upper portion of the body can be achieved by providing a pipe panel having a porous compartment structure characterized in that it forms a concave groove portion which is a path through which the heat medium circulation pipe passes.

In addition, another object of the present invention, in the ondol system applied to the floor construction of the building, it is composed of a polypropylene material body to form an air compartment structure at regular intervals, the concave groove formed on the upper portion of the body Porous piping panels; A heat medium circulation pipe coupled to the concave groove and serving to circulate the heat medium transferred from an external boiler to the front surface of the porous pipe panel; A heat dissipation iron plate uniformly transferring the heat transferred from the heat medium circulation tube to the upper layer portion; It can be achieved by providing a package ondol system comprising a; and an aluminum heat insulating material to prevent the heat present in the porous pipe panel leaks to the lower surface and to reflect the heat to the upper layer to prevent heat loss. have.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Figure 1a is a plan view of a pipe panel having a porous compartment structure according to an embodiment of the present invention, Figure 1b is an enlarged view of the edge portion of the pipe panel.

Piping panel according to an embodiment of the present invention is formed in the panel portion (40) forming the groove of the air compartment structure at regular intervals; concave groove portion 41 which is a path through which the heat medium circulation pipe passes; and the heat medium circulation pipe Is formed by forming a corner turning portion 42, which is a means for easily connecting to the heat medium circulation pipe of another piping panel.

The panel portion 40 is a honeycomb panel that forms a number of air compartments at regular intervals in light polypropylene.

The reason why the polypropylene is selected as the material of the panel part 40 is that it maintains its shape without deformation at high temperatures (up to 110 degrees), and is light, easy to handle, and easy to work with.

In addition, the effect that the panel portion 40 is exerted by forming the through-holes of the numerous air compartment structure in the body as described above is as follows.

First, since the density of the panel portion 40 decreases, the temperature of the panel body is steeply increased from the heat transmitted through the heat medium circulation tube within a short time.

Second, since the air compartment structure 43 serves as a container for storing the air whose temperature is increased by the heat medium circulation tube, the air compartment structure keeps the air whose temperature has been raised within the short time to be long to provide heat continuously. It works.

Third, the air compartment structure 43 is provided to provide a higher supporting force than when the panel body is integrated.

Fourth, the air compartment structure 43 plays a role of absorbing and dispersing in the compartment structure without transmitting all the noise vibrations generated from the upper surface of the panel portion to the bottom surface, thereby exhibiting excellent sound insulation effect.

Fifth, there is an effect that can lower the thickness of the floor when the flooring construction using the pipe panel of the present invention is applied to the high bearing capacity and the sound insulation effect by the air compartment structure.

Sixth, the air contained in the air compartment structure is heated to the upper layer after the temperature rises at a rapid rate, there is an effect that can evenly transfer heat to all the upper layers of the piping panel as well as the area in which the heat medium circulation pipe contact. This enables rapid heating and energy savings.

As shown in FIG. 2A, the air compartment structure 43 is preferably a hexagonal honeycomb structure having a columnar shape penetrating the upper and lower surfaces of the panel body.

However, the shape of the air compartment structure applied to the piping panel of the present invention is not necessarily limited to the hexagonal honeycomb structure, and the compartment structure including the shape of a square pillar as in FIG. 2B or a triangular pillar as in FIG. 2C. Can be. That is, by forming a predetermined space in the tube through the body portion of the panel, the shape of the porous pillar that provides the sound insulation and thermal insulation described above should be interpreted as being included therein.

The recessed groove portion 41 is provided as a path through which the heat medium circulation pipe passes. In particular, the piping panel of the present invention may perform piping work by combining a heat medium circulation pipe such as a hot water pipe to the concave groove part 41, which is basically provided, but the present invention selects a polypropylene that is easy to process as a material of the panel part. In the operator can freely mold the concave groove portion can select the desired pipe path.

The corner turning portion 42 is provided as a space for easily connecting the heat medium circulation pipe with the heat medium circulation pipe of another pipe panel.

Referring to FIG. 1B, the corner turning part 42 is formed at one or more positions of four corners of the panel part 40 body and is formed in a structure capable of discharging the heat medium circulation tube to an adjacent side. That is, the operator can discharge the heat medium circulation pipe in the A direction when the other pipe panel is placed in the A position through the corner turning part 42 and the floor material is installed, and when the other pipe panel is placed in the B position, the floor material is installed. The heat medium circulation pipe can be discharged in the B direction.

Figure 3a is a view for explaining the configuration of a package ondol system to which the piping panel having a porous compartment structure, Figure 3b is a side view of the package ondol system, Figure 4 is an exploded perspective view of the package ondol system.

The package ondol system of the present invention is a heating system that maintains a building at a constant temperature by circulating a thermal medium containing hot water from a boiler. In particular, the present invention is configured by applying a porous pipe panel, the heating structure to increase the sound insulation effect and thermal insulation effect.

Package ondol system according to an embodiment of the present invention for this purpose magnesium board (10); Heat dissipation plate 20; Heating medium circulation tube 30; Porous piping panel 40; And aluminum insulation material (50).

Magnesium board 10 is a first-class flame retardant product that serves to directly transfer the heat transmitted from the heat medium circulation pipe 30 to the space of the building as a material selected by replacing the existing concrete material. In particular, the magnesium board 10, the far-infrared radiation is generated to improve the health of the user, and also to replace the existing concrete material to improve the problems of the conventional sick house syndrome and the long construction period.

In particular, the present invention is applied to the porous pipe panel 40 can reduce the thickness of the magnesium board to 6 ~ 15 mm, thereby simplifying the construction of the flooring. The sound insulation effect generated by the above has been described with reference to FIGS. 1 to 3, and it has already been described above that the floor thickness can be reduced.

The heat dissipation plate 20 serves to evenly and quickly transfer the heat generated from the heat medium circulation pipe 30 to the front of the magnesium board.

As a preferred embodiment, the heat dissipation iron plate 20 is configured to prevent rust even after a long time using a galvalume iron plate or a galvanized iron plate is coated on the surface.

However, in the construction of flooring, the heat dissipation iron plate 20 may not be applicable to the case of architectural standard sizes such as 900 × 1800 mm and 1200 × 2400 mm due to manufacturing problems. The heat generated from the heat medium circulation pipe 30 can be transferred to the magnesium board by fitting into the concave iron plate 21.

That is, the heat dissipation iron plate 20 for transferring heat is used to meet the building standards, the concave iron plate 21 is used in the case of bending, cutting or custom rather than the existing standard.

The heat medium circulation pipe 30 is coupled to the concave groove 41 of the porous pipe panel 40 (see FIG. 1) to evenly circulate the heat medium including hot water delivered from an external boiler to the front surface of the porous pipe panel. Play a role.

In particular, the heat medium circulation pipe 30 as a preferred embodiment of the present invention is to use a pipe hose of TPE raw material which is an environmentally friendly material.

The pipe hose of the TPE raw material improves the problem of adversely affecting the human body due to toxic discharge, which is a problem of the conventional PVC hose, and the problem of shortening the hose life due to scale or foreign matter.

As described above with reference to FIG. 1, the porous pipe panel 40 forms a dense air compartment structure at regular intervals in the panel body of polypropylene material, thereby causing interlayer noise (July 2005), which has been a problem in the conventional wet or dry ondol process. The floor thickness of the apartment should be constructed more than 180mm due to the noise prevention standard between the floors of the multi-family houses.

The sound insulation principle and the thermal insulation principle of the porous pipe panel have already been described with reference to FIG. 1.

In addition, as a preferred embodiment of the present invention, the material of the porous pipe panel is made of polypropylene, so it is light, easy to handle, and easy to construct. That is, the package ondol system according to an embodiment of the present invention has a feature that can be provided as a customized ondol because of such an easy construction.

In more detail, the conventional dry ondol was constructed by injecting ondol panels to a standard such as 450 × 450 mm, 450 × 600 mm, and assembling each temperature panel one by one, but ondol according to an embodiment of the present invention. The system adopts the porous pipe panel, which is easy to construct using the polypropylene material described above, so that the panel is 600 × 900 mm, 900 × 900 mm, 900 × 1800 mm, 1200 × 2400 mm and smaller. It is possible to provide a small package ondol system. Thereby, the package ondol system according to the embodiment of the present invention can be provided as a custom ondol that can be appropriately sized according to each architectural drawing.

The aluminum heat insulating material 50 prevents heat from leaking to the lower surface of the air compartment structure 43 forming the through-holes on both the upper and lower sides of the pipe panel, and reflects the heat, thereby preventing heat loss. It serves to assist the heat transfer to the iron plate 20 efficiently.

In addition, the aluminum insulating material 50 also functions as a sound insulation by absorbing residual noise vibrations that are not blocked in the pipe panel.

5A to 5C are flowcharts illustrating a method of constructing ondol heating using a package ondol system according to an embodiment of the present invention.

As a method for constructing ondol heating using the package ondol system according to an embodiment of the present invention, an A-type construction method (FIG. 5A) which sequentially constructs an aluminum insulation material, a porous panel, a heat medium circulation pipe, a heat radiation iron plate, and a magnesium board In the sequence of the A-type construction method, the construction of the heat-dissipating iron plate is formed in the upper layer portion of the magnesium board B-type construction method (FIG. 5B), and to transfer heat at a higher speed to the upper layer portion of the heat medium circulation pipe at a higher speed. There is a C-type construction method (FIG. 5C) omitting the construction of the magnesium board.

As a preferred embodiment, the bonding of each construction layer of the package ondol system according to the embodiment of the present invention uses an epoxy bond certified as an environmental product that is harmless to the human body.

On the other hand, the above description is merely illustrative of the technical idea of the present invention, those of ordinary skill in the art will be able to various modifications and variations without departing from the essential characteristics of the present invention. . Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas falling within the scope of the present invention should be interpreted as being included in the scope of the present invention.

As described above, according to the present invention, there is an effect of providing a package ondol system that prevents interlayer noise, enables rapid heating, and efficiently saves energy through a pipe panel forming an air compartment structure. .

In addition, according to the present invention it is possible to free piping regardless of the structure of the building by using the pipe panel, which is easy to process, so that the general public can easily heat construction has the effect of reducing the construction cost. .

Claims (5)

In the piping panel applied to the floor construction of the building, The body of the pipe panel is made of a polypropylene material, and forms an air compartment structure that is a through hole penetrating the body at regular intervals, the upper portion of the body is formed a recessed groove that is a path through which the heat medium circulation pipe passes Tubing panel having a porous compartment structure, characterized in that. The method of claim 1, wherein the pipe panel, Piping panel having a porous compartment structure characterized in that it further forms a corner portion to enable connection with the heat medium circulation pipe of the other piping panel at one or more corners of the body. In the ondol system applied to the floor construction of the building, A porous piping panel formed of a polypropylene body forming an air compartment structure at a predetermined interval, and forming a concave groove on an upper portion of the body; A heat medium circulation pipe coupled to the concave groove and serving to circulate the heat medium transferred from an external boiler to the front surface of the porous pipe panel; A heat dissipation iron plate uniformly transferring the heat transferred from the heat medium circulation tube to the upper layer portion; And An aluminum heat insulating material which prevents heat existing in the porous pipe panel from leaking to the lower surface and reflects the heat to the upper layer to prevent heat loss; Package ondol system, characterized in that comprising a configuration. The method of claim 3, wherein the package ondol system, Magnesium board to directly transfer the heat transmitted from the heat medium circulation pipe to the space of the building; Package ondol system characterized in that it further comprises. The method of claim 3, wherein the heat medium circulation pipe, A package ondol system characterized by using a pipe hose made of TPE raw material.

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