KR101178598B1 - Prefabricated panel of dry type - Google Patents

Abstract

PURPOSE: An assembly-type dry panel is provided to easily fix heat insulating plates to a floor without deformation while the heat insulating plates are easily pressured and fixed by a pressure plate a fastener. CONSTITUTION: An assembly-type dry panel comprises a block-type heat insulating plate(10), a pipe(20), a radiating cover(30), a connector(40), and a fastener(50). The pipe is buried in an upper surface of the heat insulating plate to be exposed, and generates heat by high temperature fluids flowing through the inside of the pipe. The radiating cover shields the surface of the heat insulating plate where the pipe is buried, and radiates the heat. The connector connects the pipe buried in the heat insulating plate to the other pipe. The fastener fixes the heat insulating plate to a floor.

Description

Prefabricated Dry Panels {PREFABRICATED PANEL OF DRY TYPE}

The present invention relates to a prefabricated dry panel, and more particularly, to a prefabricated dry panel capable of heating the floor by the fluid flowing through the pipeline by being prefabricated on the floor of the residential building is connected to the pipeline.

In general, as a construction method for heating the floor of a residential building, a wet method is commonly used in which a heat-insulating dustproof layer and a bubble concrete are placed on a slab surface completed by a frame construction and plastered with heating pipes installed again. This wet method is relatively widely used in residential buildings, such as multi-family houses or apartments, to reduce the noise generated between floors in addition to the inherent purpose of heating. There was a problem that the load is increased.

Accordingly, in recent years, a dry panel in which a heat insulation dustproof layer and a heating pipe are integrally manufactured and assembled on a slab surface is used as part of improving the problems of the wet method.

There is a prefabricated ondol panel disclosed in the Republic of Korea Patent No. 10-743974 as a dry panel of the prior art. In the prior art ondol panel, as illustrated in FIG. 1, the hot water pipe 30 is zigzag in the center of the panel body 10, and the hot water pipe 30 and the upper and lower surfaces of the panel body 10 are zigzag. Meshes 40 and 40 'are respectively installed therebetween, and coupling grooves 11 are formed on one side of the panel body 10, and the inlet portion 31 of the hot water pipe 30 is the coupling grooves 11. ) And the discharge portion 32 is protruded to the other side of the panel body 10, the one-touch coupling member 50 is coupled to the end of the inlet portion 31, the inlet portion 31 The coupling member 50 is configured to be coupled to the discharge portion (32).

However, since the hot water pipe 30 is completely embedded in the panel body 10 as shown in FIG. 1 in order to maintain the flatness of the panel body 10, the hot water pipe 30 is heated. There is a problem that heat loss occurs because the heat radiation to the upper portion of the panel body (10). In addition, the ondol panel of the prior art also has a problem that the installation of the panel body 10 is impossible due to the lack of a configuration that can be fixed to the floor with the panel body 10 with another panel body.

On the other hand, the ondol construction panel disclosed in the Republic of Korea Utility Model Registration No. 20-204241 embeds a heating hose 22 in the recessed groove 12 of the heat sink 10 constituting the panel as shown in Figure 2 (a) And the concave indentation groove 12 with the cover 26 to improve the thermal efficiency of the heating hose 22.

However, such a conventional ondol construction panel has a problem that a separate cover 26 must be constructed to provide a flatness of the heat sink 10. In addition, bending occurs due to the space generated between the end of the cover 26 and the heat sink 10, and the panel durability is increased as a space is formed between the circular heating hose 22 and the cover 26. There is also a problem of deterioration.

On the other hand, the dry heating ondol panel disclosed in the Republic of Korea Patent No. 10-0649485 is a hot water pipe 25 is formed in a rectangular oval shape as shown in Figure 2 (b) is embedded in the lower plate 21 As the upper plate 22 is in close contact, the heat loss of the hot water pipe 25 is reduced and the flatness of the upper plate 22 is maintained.

However, such an ondol panel has a problem in that energy efficiency is lowered because a large amount of hot water flows through the hot water pipe 25 is formed in a rectangular shape so that the hot water flows through the hot water pipe 25 and another panel of the hot water pipe 25. In order to connect to the hot water pipe of the hot water pipe 25, there is also a cumbersome problem of making a connector having the same shape as the conduit or forming a connection portion of the hot water pipe 25 in a form corresponding to the connector.

On the other hand, the prefabricated heating tube disclosed in Republic of Korea Utility Model Publication No. 20-1989-2759 has a wing-shaped heat conduction plate (2) integrally formed on the upper portion of the water pipe (1) as shown in Figure 2 (c) It is formed and is configured to conduct the heat of the water pipe 1 to the upper plate 4.

However, the conventional heating tube has a problem that the heat conduction efficiency is lowered since the heat conduction plate 2 is formed in a wing shape having a wider width than the water pipe 1 and protrudes to both sides of the water pipe 1, and the material cost is of course increased. Since the bending of the water pipe 1 is impossible, in order to install it in a zigzag form on the panel, a separate 'U'-shaped connector has to be manufactured and connected to the water pipe 1.

KR 10-0743974 B1 KR 20-0204241 Y1 KR 10-0649485 B1 KR 20-1989-2759 Y1

The present invention has been made to solve the problems of the prior art described above, by exposing a pipe that generates heat by a high-temperature fluid on the upper surface of the heat insulating plate to improve the heat generating efficiency, in particular the exposed portion of the pipe is bent or spaced An object of the present invention is to provide a prefabricated dry panel that can form a bottom surface firmly by forming a horizontal surface with a heat insulating plate without generating a space.
In particular, it is an object of the present invention to provide a prefabricated dry panel that can be easily fixed to a plurality of insulating plates in a connected state.

Prefabricated dry panel of the present invention for achieving the above object, the block-shaped heat insulating plate made of a heat insulating material; A pipe in the form of a pipe which is embedded in an upper surface of the heat insulating plate and generates heat by a high temperature fluid flowing through the inside; A heat dissipation cover that radiates heat of the pipe while shielding a surface of the heat insulation plate on which the pipe is embedded; A connector for connecting the pipe embedded in the heat insulating plate to a communication state with another pipe embedded in another heat insulating plate adjacent to the heat insulating plate; And a fastener configured to fix the heat insulating plate and the another heat insulating plate to the floor in an adjoining state, wherein the pipe has a horizontal portion on an outer circumferential surface thereof as formed in a semicircular cross section having a pipe through which the fluid flows. The horizontal portion is formed in a horizontal plane with the heat insulating plate in the state exposed to the upper surface of the heat insulating plate, characterized in that the horizontal portion facing or in close contact with the heat dissipation cover.
Here, the fastener has, for example, a post that is vertically sandwiched between the heat insulating plate and the another heat insulating plate, both sides of the heat insulating plate and the other heat insulating plate as the same as the post is seated on the top surface of the heat insulating plate and another heat insulating plate and A pressure plate for pressing the another heat insulation plate; And a fixing bolt fastened to the bottom while penetrating the post of the pressing plate.

The prefabricated dry panel according to the present invention as described above, since the pipe providing high heat is embedded in the state exposed to the upper surface of the heat insulating plate can be provided on the top of the heat insulating plate without losing heat of the pipe, in particular the pipe is semi-circular Since the horizontal part forms a horizontal plane together with the insulation board, the upper surface of the insulation board can be manufactured in a horizontal state without a separate horizontal member, and the pipes are firmly embedded in a state in which the pipe is in close contact with the insulation board, thereby improving heat transfer and durability. have.
In particular, since the heat insulating plate and another heat insulating plate adjacent to each other by the fastener is pressed and fixed by the pressure plate can be easily fixed to the bottom surface without penetrating or deforming the heat insulating plate or another heat insulating plate.

1 is a perspective view showing a dry panel of the prior art.
Figure 2 is a longitudinal sectional view showing a dry panel of the prior art.
Figure 3 is an exploded perspective view showing a prefabricated dry panel according to the present invention.
Figure 4 is a longitudinal sectional view showing a prefabricated dry panel according to the present invention.
5 is a perspective view of the connector of the present invention.
6 is a perspective view showing a fastener of the present invention.
Figure 7 is a state diagram showing the installation state of the prefabricated dry panel according to the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted.

The prefabricated dry panel according to the present invention may include a heat insulating plate 10, a pipe 20, a heat dissipation cover 30, a connector 40 and a fastener 50 as shown in Figs. .

Insulation plate 10 is a member that is continuously installed on the slab forming the floor of the building, as shown in Figure 3 made of a heat insulating material in the form of a square or rectangular block is installed continuously as shown in FIG. .

The heat insulating plate 10 has a buried groove 11 in which the pipe 20 to be described later is embedded, as shown in FIG. 3, and the seating jaw 13 having a stepped shape is provided along the edge to provide a pressure plate 51 to be described later. Settle down.

The pipe 20 is a pipe member that generates heat by a high temperature fluid flowing through the inside, and is embedded in an exposed state in the buried groove 11 provided in the heat insulating plate 10 as shown in FIG. 3. The pipe 20 may be made of an aluminum material having excellent thermal conductivity, and is connected to an unshown boiler so that hot water heated in the boiler flows through the pipe line 21 to heat the hot heat of the insulation plate 10. Provide on the top. Alternatively, the pipe 20 may be made of a conventional material used for heating.

Here, the pipe 20 has a horizontal portion 23 in the upper portion as formed in a semi-circular cross section as shown in Figure 3, the horizontal portion 23 is embedded in the heat insulating plate 10, the horizontal portion 23 and the horizontal surface Exposed while being in close contact with or facing the heat dissipation cover 30 to be described later.

Therefore, the pipe 20 radiates high-temperature heat to the upper portion of the heat insulating plate 10 while providing a horizontal surface by the horizontal portion 23 without forming a bend on the top surface of the heat insulating plate 10, and the buried groove 11. As there is no space spaced apart from the buried groove (11) closely supports the load applied from the top of the heat insulating plate (10).

On the other hand, the pipe 20 may be connected to the connector 40 to be described later, regardless of the semi-circular shape as the pipeline 21 through which the fluid flows is formed in a circular shape as shown in FIG.

The heat dissipation cover 30 heats the heat of the pipe 20 while shielding the surface of the heat insulating plate 10 in which the pipe 20 is embedded, as shown in FIG. 4. The heat dissipation cover 30 is preferably composed of a galvanized steel sheet called galvanium, for example, as shown in FIG. Heat dissipate

The connector 40 is a component that connects the pipe 20 in communication with the pipe 20 'embedded in another heat insulating plate 10' as shown in FIG. 3, for example, as shown in FIG. It can be configured to include a connecting pipe 41, overlapping pipe 43 and the packing (45).

As shown in FIG. 5, the connecting pipe 41 is a member connected to the pipe 20 or another pipe 20 ′ in an inserted state, and a plurality of pipes 20 are formed as shown in the upper part of FIG. 5. ) And another pipe 20 ', respectively, and alternatively, as shown in the lower part of FIG. 5, a single stage may be inserted into only one pipe 20'.

The overlapping pipe 43 is a member for elastically communicating the connecting pipe 41. When the connecting pipe 41 is configured in plural, each of the connecting pipes 41 is disposed at both sides as shown in the upper part of FIG. 5. Inserted in an overlapping state to communicate the pipe 20 and another pipe 20 ', when the connecting pipe 41 is composed of a singular, as shown in the lower portion of Figure 5 the connecting pipe 41 is inserted into one side While directly connected to the pipe 20 through the nipple (43a) formed on the other side in a state to communicate the pipe 20 and another pipe 20 '.

The overlapping tube 43 stretches the connecting tube 41 while drawing or drawing the connecting tube 41 as shown in FIG. 5. In detail, the overlapping pipe 43 may expand and contract the connecting pipe 41 according to the spaced distance of the pipes 20 and 20 ', that is, the spaced apart distances of the heat insulating plates 10 and 10'. Communicate with 20 '.

On the other hand, the overlap pipe 43 may be formed in a curved shape of the 'U' shape as shown in the lower portion of FIG.

Packing 45 is provided at the end of the connecting pipe 41 as shown in Figure 5 seals the connecting pipe 41 while being in close contact with the inner peripheral surface of the pipe 20 and the overlapping tube 43.

On the other hand, the connector 40 may be configured to further include a fixing member 47 for fixing the connecting pipe 41 drawn out from the overlapping pipe 43 in the drawn state.

The fixing member 47 is fixed to prevent the flow of the connection pipe 41 while being caught at the end of the overlapping pipe 43 as it is coupled to the lead portion of the connection pipe 41, for example, as shown in FIG. Can be configured as a clip.

Here, the fixed clip is formed to a length corresponding to the withdrawal distance of the connecting pipe 41 as shown in Figure 5 so that both ends are caught in the overlapping pipe 43 and the end of the pipe 20 flow of the connecting pipe 41 Can be prevented.

The fastener 50 is a component for fixing the heat insulating plate 10 and another heat insulating plate 10 'to the floor in an adjacent state, and includes, for example, a pressing plate 51 and a fixing bolt 53 as shown in FIG. 3. Can be configured.

The pressure plate 51 is a member that presses the heat insulating plates 10 and 10 'in an adjacent state, and as illustrated in FIG. 3, the pressure plate 51 is vertically fitted between the heat insulating plates 10 and 10 ′. 52, and both ends are seated on the seating jaws 13 and 13 'described above.

Fixing bolt 53 is fastened to the bottom while passing through the post 52 as shown in FIG.

That is, the pressure plate 51 is fixed to the floor by the fastening force of the fixing bolt 53 in the state seated on the mounting jaw (13, 13 ') while pressing and fixing the heat insulating plates (10, 10').

Here, the post 52 is damped rubber (52a) is provided on the outer peripheral surface as shown in Figure 4 is in close contact with the insulating plates (10, 10 ') to damp the flow of the insulating plates (10, 10') Can be.

Meanwhile, the fastener 50 may further include an additional pressure plate 51 ′ and a cutter 57 as shown in FIG. 6.

The additional pressure plate 51 ′ is formed in the same manner as the pressure plate 51 as shown in FIG. 6 and is provided in a continuous state on the side of the pressure plate 51 while forming the same body as the pressure plate 51. The additional pressing plate 51 ′ may be continuous in one side or both sides of the pressing plate 51 or in all directions of the pressing plate 51 as shown in FIG. 6.

As shown in FIG. 6, the cutter 57 is formed in a groove shape at a connection portion between the pressure plate 51 and the additional pressure plate 51 ′ and a connection portion between the additional pressure plate 51 ′ to cut each connection portion. Connect.

Accordingly, the pressing plate 51 and the additional pressing plate 51 ′ may be cut into a shape corresponding to the edge of the insulating plate 10 as shown in FIG. 6.

Specifically, as the pressure plate 51 and the additional pressure plate 51 'is cut by the cutter 57, as shown in FIG. ) 10 'to the ground.

It describes the installation and assembly process of the prefabricated dry panel according to the present invention comprising the above components.

The operator connects the pipe 20 to another adjacent pipe 20 'while sequentially arranging a plurality of heat insulating plates 10 provided on the floor according to the floor area.

At this time, the worker withdraws the connecting pipe 41 inserted in both sides of the overlapping pipe 43 to the length corresponding to the separation distance of the pipes 20, 20 'as shown in FIG. And 20 'are inserted into the conduits 21, respectively, and the fixing clips 47 are fastened to the connecting pipes 41 to fix the connecting pipes 41 in the drawn state.

Accordingly, the pipes 20 and 20 'are in communication with each other to circulate the heat insulating plates 10 and 10' as shown in FIG.

Subsequently, the operator inserts the post 52 of the pressure plate 51 between the heat insulation plates 10, 10 ′ as shown in FIG. 3, so that both ends of the pressure plate 51 are insulated from the heat insulation plates 10, 10 ′. And the heat insulating plates 10 and 10 'are pressed by the pressure plate 51 by fastening the fixing bolts 53 to the bottom surface through the posts 52. Fix it in the state.

At this time, the operator cuts the pressure plate 51 and the additional pressure plate 51 'of the continuous state through the cutter 57 as shown in Figure 6 in a shape that corresponds to the edge of the insulating plates 10, 10'. Fixing the insulation plates 10, 10 'to the bottom surface.

Then, the worker connects the pipe 20 to the distributor of the boiler not shown.

Accordingly, the dry panel of the present invention forms the ondol floor of the building while generating heat by a high temperature fluid flowing through the pipe line 21 of the pipe 20.

As described above, according to the prefabricated dry panel according to the present invention, since the pipe 20 providing high heat is embedded in the state exposed to the upper surface of the heat insulating plate 10, the pipe 20 is provided on the heat insulating plate 10 without losing heat of the pipe. In particular, since the pipe 20 is made of a semi-circular cross-section, the horizontal portion 23 forms a horizontal plane with the heat insulating plate 10, so that the top surface of the heat insulating plate 10 can be manufactured in a horizontal state without a separate horizontal member. In addition, since the pipe 20 is firmly embedded in the heat insulating plate 10 in close contact, heat transfer and durability may be improved.

In addition, since the connecting pipe 41 constituting the connector 40 is inserted into the overlapping pipe 43 so as to be pulled out, the pipes 20 and 20 'can be expanded and contracted according to the separation distance of the pipes 20 and 20'. ) Can be connected by sealing them in communication.

In addition, since the connection tube 41 is fixed in the state drawn out from the overlapping tube 43 by the fixing clip 47 constituting the fixing member, the flow is prevented, so that the connecting tube 41 at the pipe 20 during operation. Arbitrary separation can be prevented.

In addition, since the heat insulating plates 10 and 10 ′ are fixed while being pressed by the pressure plate 51 in an adjacent state, the heat insulating plates 10 and 10 ′ may be fixed to the bottom surface without penetrating or deforming the heat insulating plate 10.

In particular, since the additional pressing plate 51 ′ is provided in the continuous state in the pressing plate 51 so as to be cut by the cutter 57, the pressing plates 51 and 51 ′ can be mass-produced in the form of a module. The pressure plate 51 and the additional pressure plate 51 ′ may be cut and used in a shape that matches the length or edge of the heat insulating plate 10.

While specific embodiments of the present invention have been described above by way of example, these are for illustrative purposes only and are not intended to limit the protection scope of the present invention. It will be apparent to those skilled in the art that various changes, substitutions, and alterations can be made therein without departing from the spirit of the invention.

10: insulation plate 11: landfill groove
13: seating jaw 20: piping
21: pipeline 23: horizontal portion
30: heat dissipation cover 40: connector
41: connector 43: nesting tube
45 packing 47 fixing member
50: fastener 51: pressure plate
52: post 52a: damping rubber
53: fixing bolt 51 ': additional pressure plate
57: cutter

Claims (5)

Block insulation board 10 made of a heat insulating material;
A pipe 20 of a pipe type embedded in an exposed state on an upper surface of the heat insulating plate 10 and generating heat by a high temperature fluid flowing through the inside;
A heat dissipation cover 30 for dissipating heat of the pipe 20 while shielding the surface of the heat insulating plate 10 in which the pipe 20 is embedded;
Connector 40 for connecting the pipe 20 embedded in the heat insulating plate 10 in communication with another pipe 20 'embedded in another heat insulating plate 10' adjacent to the heat insulating plate 10. ; And
And a fastener 50 for fixing the heat insulating plate 10 and the another heat insulating plate 10 'to the floor in an adjacent state.
The pipe 20 is,
As the fluid is formed in a semicircular cross section having a conduit 21 through which the fluid flows, the fluid has a horizontal portion 23 on its outer circumferential surface, and the heat insulating plate (3) is exposed to the upper surface of the heat insulating plate 10. 10 and the horizontal portion 23 to form a horizontal surface with the heat dissipation cover 30, or is in close contact with,
The fastener 50,
It has a post 52 which is fitted vertically between the heat insulating plate 10 and the another heat insulating plate 10 ', both sides of the heat insulating plate 10 and the another heat insulating plate while forming the same as the post 52 A pressure plate 51 for pressing the heat insulating plate 10 and the another heat insulating plate 10 'as it is seated on an upper surface of the 10'; And
Prefabricated dry panel comprising a; fixing bolt 53 is fastened to the bottom while passing through the post of the pressure plate (51). The method of claim 1, wherein the connector 40,
At least one connecting pipe 41 connected to an end of another pipe 20 'embedded in the pipe 20 or another heat insulating plate 10';
The connecting pipe 41 is inserted in an overlapping state on one side and directly connected to the pipe 20, or a plurality of connecting pipes 41 are respectively inserted in the overlapping state on both sides to communicate with each of the connecting pipes 41. And an overlapping pipe 43 for stretching the connecting pipe 41 while drawing out the connecting pipe 41 according to the separation distance of the pipe 20 or another pipe 20 '; And
And a packing (45) provided at an end of the connection pipe (41) to seal the connection pipe (41) while being in close contact with the pipe (20) and the overlapping pipe (43). The method of claim 2, wherein the connector 40,
And a fixing member 47 for fixing the connection pipe 41 to be drawn out from the overlapping pipe 43.
The fixing member 47,
It is coupled to the lead portion of the connecting pipe 41 is fixed to the end of the overlapping pipe 43, the fixing clip to prevent the connection pipe 41 is introduced into the overlapping pipe 43; Prefabricated dry panels. delete The method of claim 1, wherein the fastener 50,
An additional pressurizing plate 51 'which is formed in the same manner as the pressurizing plate 51 and forms the same body at the end of the pressurizing plate 51, and is continuously formed laterally; And
A groove-shaped cutter 57 for cutting the rigidity of the connection portion between the additional pressing plate 51 'and the pressing plate 51 so that the additional pressing plate 51' is cutably connected to the pressing plate 51; Include,
The pressure plate 51 and the additional pressure plate 51 ',
Prefabricated dry panel, characterized in that cut by the cutter (57) to match the shape of the edge of the heat insulating plate (10) and the other heat insulating plate (10 ').

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