KR20110134078A - Prefabricated hypocaust panel for heating and method of aseembling - Google Patents

Abstract

PURPOSE: A prefabricated ondol panel for heating and an assembling method thereof are provided to easily assemble and construct ondol panels according to the size of a room. CONSTITUTION: A prefabricated ondol panel for heating comprises a first ondol panel(10). The first ondol panel has an L-shaped flow path(1). Mounting units(2) are formed in both ends of the flow path. Each mounting unit is composed of a male connection pipe(3) and a mounting protrusion(4). The male connection pipes are connected to the flow path and have O-ring grooves(3a). The mounting protrusions are located at both sides of the male connection pipes and have fixing grooves(4a) in which fixing members are inserted.

Description

Prefabricated hypocaust panel for heating and method of aseembling}

The present invention relates to a prefabricated ondol panel for heating and a method for assembling a heating fluid having a heating function, and in particular, a prefabricated ondol for heating that can be assembled more easily by constructing a mounting structure of each ondol panel having a flow path formed therein with a male and female structure. It relates to a panel and an assembly method.

In general, the heating space of residential life in Korea is common to the construction of ondol which embeds a heating water pipe using cement mortar.

Such ondol construction is usually made of a process of laying a foamed resin insulation plate on the concrete foundation floor, piping the heating water pipes, filling the heat storage material such as gravel sand, and then applying cement mortar again.

However, in the case of the above, there was a problem that damage to neighbors because noise pollution occurs during construction.

In addition, there was a problem of freezing during the construction of the mortar in winter, labor costs and expenses incurred unnecessarily due to the long time of solidification of the mortar, and there was a problem that the efficiency of the work was reduced due to the reduction of the construction progress due to the complicated process work. .

Accordingly, the present invention has been made in view of the problems of the prior art as described above, by constructing the mounting structure of each ondol panel with a flow path through which a heating fluid can flow, consisting of a male and female structure, can be easily assembled and constructed during construction. The purpose of the present invention is to provide a prefabricated ondol panel for heating and an assembly method that can be constructed regardless of season and place.

In order to achieve the above object, the present invention provides a prefabricated ondol panel for heating and assembly method, which is installed on an indoor floor and receives heating fluid from a boiler for heating.

A first ondol panel having a flow path having a '┏' shape formed therein and having mounting portions at both ends of the flow path,

The flow path 1 of the '┃┃' shape is formed in both sides in the longitudinal direction, the female connection portion 11 is formed at one end of the flow path 1, respectively, the male connection portion 12 at the other end of the flow path (1) The second ondol panel 20 is formed, respectively,

A third ondol panel having a 'Ｕ'- shaped flow path formed therein and having mounting portions formed on the same surface at both ends of the flow path,

A fourth ondol panel having a long one side and a short '┎'-shaped flow path formed therein and having mounting portions at both ends of the flow path,

A prefabricated ondol panel for heating and a method of assembling are assembled using a fifth ondol panel in which a '┃'-shaped flow path is formed in the longitudinal direction, a female connection part is formed at one end of the flow path, and a male connection part is formed at the other end of the flow path. to provide.

As described above, the present invention can achieve cost reduction due to the speed of work and the simplification of the process, and can be constructed regardless of season and place since it is completely dry heating, and there is an effect of reducing noise pollution during construction.

In addition, even if the size of the room is not standardized, there is an effect that can facilitate the construction of the ondol by assembling each ondol panel according to the size of the room.

In addition, since it is possible to easily assemble and combine each temperature panel rather than a complicated and difficult process, there is an effect that anyone can be easily installed even if a skilled worker.

1 is a plan view showing a state in which the mounting portion according to the present invention has a male structure (a) is a copper tube without a state, (b) is a plan view showing a state in which the copper tube is inserted.
Figure 2 is an exploded perspective view showing a state in which the mounting portion according to the invention the first ondol panel made of a male structure consisting of upper and lower bodies.
Figure 3 is an exploded perspective view showing a state in which the copper tube is inserted into the flow path of the upper body, the lower body of the first ondol panel made of a mounting structure according to the present invention.
Figure 4 is a plan view showing a state (a) of the first ondol panel mounting portion made of a female structure in accordance with the present invention without a copper tube, (b) is a plan view showing a state in which the copper tube is inserted.
Figure 5 is an exploded perspective view showing a state in which the mounting portion according to the invention the first ondol panel made of a female structure consisting of the upper, lower body.
Figure 6 is an exploded perspective view showing a state in which the copper tube is inserted into the flow path of the upper body, the lower body of the first ondol panel made of a mounting structure according to the present invention.
Figure 7 is a use state showing the assembled state of the first ondol panel according to an embodiment of the present invention.
8 is a plan view showing that the female connecting part and the male connecting part according to the present invention have a male-and-female structure, the second ondol panel is injection molded without a copper tube, and (b) is a plan view showing the injection molding by inserting a copper tube.
9 is an exploded perspective view showing a state in which a female connecting portion and a male connecting portion according to the present invention are configured with upper and lower bodies of a second ondol panel made of a male and female structure.
10 is an exploded perspective view showing a state in which the copper tube is inserted into the upper body of the lower body, the upper body of the second ondol panel, the female connector, the male connector according to the present invention.
11 is a use state showing the assembled state of the second ondol panel according to an embodiment of the present invention.
12 is a plan view showing a state in which the copper tube is inserted, (a) is a plan view showing a state in which the copper tube is inserted, and (b) of the third ondol panel made of a female structure with a mounting portion according to the present invention.
Figure 13 is an exploded perspective view showing a state in which the mounting portion according to the invention the third ondol panel made of a female structure consisting of upper and lower bodies.
Figure 14 is an exploded perspective view showing a state in which the copper tube is inserted into the flow path of the upper body, the lower body of the third ondol panel mounting portion made of a female structure according to the present invention.
Figure 15 is a plan view showing a state in which the copper tube is inserted, (a) is a plan view showing a state in which the copper tube is inserted, (a) of the third ondol panel made of a male structure mounting portion according to the present invention.
Figure 16 is an exploded perspective view showing a state in which the mounting portion according to the invention the third ondol panel consisting of a male structure of the upper, lower body.
17 is an exploded perspective view showing a state in which the copper tube is inserted into the flow path of the upper body and the lower body of the third ondol panel made of a mounting portion according to the present invention.
18 is a use state showing the assembled state of the third ondol panel according to an embodiment of the present invention.
19 is a plan view showing a state in which the mounting part according to the present invention has a male structure (a) is a copper tube is not present, (b) is a plan view showing a state in which the copper tube is inserted.
20 is an exploded perspective view showing a state in which the mounting portion according to the invention the fourth ondol panel made of a male structure consisting of upper and lower bodies.
Figure 21 is an exploded perspective view showing a state in which the copper tube is inserted into the flow path of the upper body, the lower body of the third ondol panel mounting portion made of a male structure.
Figure 22 is a plan view showing a state in which the copper tube is inserted (a) is a plan view showing a state in which the copper tube is inserted, the (a) of the fourth ondol panel made of a female structure of the mounting portion according to the present invention.
Figure 23 is an exploded perspective view showing a state in which the mounting portion according to the invention the fourth ondol panel made of a female structure consisting of the upper, lower body.
Figure 24 is an exploded perspective view showing a state in which the copper tube is inserted into the flow path of the upper body, the lower body of the third ondol panel mounting portion made of a female structure according to the present invention.
25 is a use state showing the assembled state of the fourth ondol panel according to an embodiment of the present invention.
26 is a plan view showing a state in which a copper tube is inserted, (a) is a plan view showing a state in which a copper tube is not inserted, and (b) is a plan view showing a state in which a copper tube is inserted.
27 is an exploded perspective view showing a state in which a female connecting portion and a male connecting portion according to the present invention are configured with upper and lower bodies of a second ondol panel made of a male and female structure.
FIG. 28 is an exploded perspective view showing a state in which a copper tube is inserted into a channel of an upper body and a lower body of a second ondol panel formed of a male and female parts and a male connector according to the present invention;
Figure 29 is a use state showing the assembled state of the fifth ondol panel according to an embodiment of the present invention.
Figure 30 is a use state showing the assembly method of the prefabricated ondol panel for heating.
Figure 31 is a use state showing the assembly method of the heating prefabricated ondol panel 2.
32 is a use state showing the assembly method of the heating prefabricated ondol panel 3.
Figure 33 is a use state showing the assembly method of the prefabricated ondol panel for heating 4.

When described in detail on the basis of the accompanying drawings a preferred embodiment of the present invention as described above are as follows.

As shown in (a) of FIG. 1, the first ondol panel 10 having a male structure in which the mounting portion 2 connected to the female structure of another ondol panel is made of a male structure has a flow path having a '┏' shape therein ( 1) is formed, the mounting portion (2) is formed at both ends of the flow path (1), the mounting portion (2) is formed in connection with the flow path (1) O-ring 60 is fitted to prevent the leakage of the heating fluid It consists of a male connecting pipe (3) having a groove (3a) and a mounting protrusion (4) having a fixing groove (4a) into which the fixing member (70) is inserted into both sides of the male connecting pipe (3). Injection molding.

As shown in (b) of FIG. 1, the copper tube 80 is inserted into the channel 1 of the first ondol panel 10 to prevent leakage of the heating fluid, thereby increasing heating efficiency. Injection molding.

Here, the first ondol panel 10 may be made of FRP or polypropylene.

In addition, to reduce the weight in a line that does not harm the configuration of the first ondol panel 10 can be produced by forming a square or circular groove.

As shown in FIG. 2, the first ondol panel 10 includes upper and lower bodies 7 and 8 to correspond to each other. The upper and lower bodies 7 and 8 are coupled to each other by ultrasonic welding.

Here, the fixing member 70 forms the outer circumferential surface with a screw line, and the fixing groove 4a forms the inner circumferential surface with a screw line so that the gaps can be fixed so as not to be opened during each ondol panel connection assembly.

In addition, the mounting protrusion 4 may be manufactured to be assembled in a snap-fit method.

As shown in Figure 3, by inserting a copper tube (80) to increase the heating efficiency while preventing the leakage of the heating fluid inside the flow path (1) of the upper body, the lower body (7) (8) by ultrasonic welding method Combine with each other.

As shown in (a) of FIG. 4, the first ondol panel 10 having a female structure in which the mounting portion 2 connected to the male structure of another ondol panel is formed of a female structure has a flow path having a '┏' shape therein. 1) a female connection groove 5 formed to be connected to each other, and a fixing hole 6a penetrating through the upper side of the first ondol panel 10 to both sides of the female connection groove 5 and into which the fixing member 70 is inserted. It consists of the mounting groove (6) provided is integrally injection molded.

As shown in (b) of FIG. 4, the insert injection unit is inserted into the flow path 1 of the first ondol panel 10 by inserting a copper tube 80 which further increases heating efficiency while preventing leakage of the heating fluid. Form.

As shown in FIG. 5, the first ondol panel 10 includes upper and lower bodies 7 and 8 to correspond to each other. The upper and lower bodies 7 and 8 are coupled to each other by ultrasonic welding.

Here, the fixing member 70 forms an outer circumferential surface with a screw line, and the fixing hole 6a forms an inner circumferential surface with a screw line so as to fix the gap so that a gap does not open during each ondol panel connection assembly.

In addition, the mounting groove 6 can be manufactured to be assembled in a snap-fit method.

As shown in Figure 6, by inserting a copper tube (80) to increase the heating efficiency while preventing the leakage of the heating fluid inside the flow path (1) of the upper and lower bodies (7) (8) by ultrasonic welding method Combine with each other.

As shown in FIG. 7, the first ondol panel 10 receives a heating fluid from a boiler and converts the flow direction of the heating fluid to another ondol panel.

Here, the first ondol panel 10 may send the heating fluid to the boiler according to the flow direction of the heating fluid.

As shown in (a) of FIG. 8, the flow path 1 having a '┃┃' shape is formed in both sides of the inside in a length direction, and a female connection part 11 is formed at one end of the flow path 1, and the flow path (1) The female connection portion 12 is formed at the other end, and the female connection portion 11 of the second ondol panel 20, which is assembled and connected with the water structure of the other ondol panel, is connected to the female channel. And a mounting groove 16 having a fixing hole 16a through which the fixing member 70 is inserted and penetrated to the upper surface of the second ondol panel 20 to both sides of the female connecting groove 15.

The male connecting portion 12 of the second ondol panel 20 connected to the female structure of the other ondol panel is connected to the flow path 1 and has an O-ring groove 13a in which an O-ring 60 is fitted on the outer circumferential surface thereof. It consists of a male connecting tube 13 and a mounting protrusion 14 having a fixing groove 14a into which the fixing member 70 is inserted into both sides of the male connecting tube 13, thereby integrally injection molding.

As shown in (b) of FIG. 8, the insert injection unit is inserted into the flow path 1 of the second ondol panel 20 by inserting a copper tube 80 which further improves heating efficiency while preventing leakage of the heating fluid. Form.

Here, the second ondol panel 20 may be made of FRP or polypropylene.

In addition, in order not to harm the configuration of the second ondol panel 20 can be produced by forming a square or circular groove to reduce the weight.

As shown in Figure 9, the second ondol panel 20 is configured to correspond to each other, the upper body and the lower body (17, 18). The upper and lower bodies 17 and 18 are coupled to each other by ultrasonic welding.

Here, the fixing member 70 is formed with an outer circumferential surface with a screw line, and the fixing hole 16a and the fixing groove 14a are formed with a screw line so as to fix the gap so as not to open a gap when assembling each ondol panel. do.

In addition, the mounting groove 16 and the mounting protrusion 14 may be manufactured to be assembled in a snap-fit method.

As shown in Figure 10, by inserting a copper tube (80) to increase the heating efficiency while preventing the leakage of the heating fluid inside the flow path (1) of the upper and lower bodies (17, 18) by ultrasonic welding method Combine with each other.

As shown in FIG. 11, the flow paths 1 formed on both sides of the second ondol panel 20 serve to circulate the flow direction of the heating fluid by opposing each other.

As shown in (a) of FIG. 12, the third ondol panel 30 having a female structure having the mounting portion 22 connected to and assembled with another male structure of the ondol panel has a ' 내부 ' shape therein. (1) is formed, the mounting portion 22 is formed on the same surface at both ends of the flow path (1), the mounting portion 22 of the third ondol panel 30 is a female connecting groove formed in connection with the flow path (1) And a mounting groove 26 having a fixing hole 26a through which the fixing member 70 is inserted, penetrating to the upper surface of the third ondol panel 30 on both sides of the female connecting groove 25. By injection molding.

As shown in FIG. 12 (b), the insert injection unit is inserted into the flow path 1 of the third ondol panel 30 by inserting a copper tube 80 which further improves heating efficiency while preventing leakage of the heating fluid. Form.

Here, the third ondol panel 30 may be made of FRP or polypropylene.

In addition, to reduce the weight in the line does not harm the configuration of the third ondol panel 30 can be produced by forming a square or circular groove.

As shown in Figure 13, the third ondol panel 30 is composed of upper and lower bodies 27, 28 to correspond to each other. The upper and lower bodies 27 and 28 are coupled to each other by ultrasonic welding.

Here, the fixing member 70 forms the outer circumferential surface with a screw line, and the fixing hole 26a forms the inner circumferential surface with a screw line so as to fix the gap so that a gap does not open during each ondol panel connection assembly.

In addition, the mounting groove 26 can be manufactured to be assembled in a snap-fit method.

As shown in Figure 14, by inserting the copper tube 80 to prevent the leakage of the heating fluid in the flow path (1) of the upper body, the lower body 27, 28 to further increase the heating efficiency by ultrasonic welding method Combine with each other.

As shown in (a) of FIG. 15, the third ondol panel 30 having a male structure in which the mounting portion 22 connected to the female structure of another ondol panel is made of a male structure has a flow path having a ' Ｕ ' shape therein. (1) is formed, the mounting portion 22 is formed on the same surface at both ends of the flow path (1), the mounting portion 22 of the third ondol panel 30 is connected to the water connection pipe (1) (23) and the mounting protrusions 24 having a fixing groove 24a into which the fixing member 70 is inserted into both sides of the male connecting pipe 23 are integrally formed by injection molding.

As shown in FIG. 15 (b), the insert injection is integrally inserted into the flow path 1 of the third ondol panel 30 by inserting a copper tube 80 which further improves heating efficiency while preventing leakage of the heating fluid. Form.

As shown in Figure 16, the third ondol panel 30 is composed of upper and lower bodies 27, 28 to correspond to each other. The upper and lower bodies 27 and 28 are coupled to each other by ultrasonic welding.

Here, the fixing member 70 forms the outer circumferential surface with a screw line, and the fixing groove 24a forms the inner circumferential surface with a screw line so as to fix the gap so that the gap does not open during each ondol panel connection assembly.

In addition, the mounting protrusion 24 may be manufactured to be assembled in a snap-fit method.

As shown in FIG. 17, the copper tube 80 is inserted into the flow path 1 of the upper and lower bodies 27 and 28 to prevent the leakage of the heating fluid and further increase the heating efficiency. Combine with each other.

As shown in Figure 18, the third ondol panel 30 has a flow path (1) formed therein serves to continuously flow the heating fluid.

As shown in (a) of FIG. 19, the fourth ondol panel 40 having a male structure in which the mounting portion 32 connected to the female structure of the other ondol panel is made of a male structure has one side long and one side short '. A flow path 1 having a '형성' shape is formed, and mounting portions 32 are formed at both ends of the flow path 1, and the mounting portion 32 of the fourth ondol panel 40 is connected to the flow path 1 and formed on an outer circumferential surface thereof. O-ring (60) is fitted with an o-ring groove (33a) is provided with a male connector (33), a mounting protrusion provided with a fixing groove (34a) is inserted into the fixing member 70 on both sides of the male connector (33) It is composed of 34 to be integrally injection molded.

As shown in FIG. 19 (b), the insert injection unit is inserted into the flow path 1 of the fourth ondol panel 40 by inserting a copper tube 80 which further improves heating efficiency while preventing leakage of the heating fluid. Form.

Here, the fourth ondol panel 40 may be made of FRP or polypropylene.

In addition, to reduce the weight in a line that does not harm the configuration of the fourth ondol panel 40 can be produced by forming a square or circular groove.

As shown in FIG. 20, the fourth ondol panel 40 includes upper and lower bodies 37 and 38 to correspond to each other. The upper and lower bodies 37 and 38 are coupled to each other by ultrasonic welding.

Here, the fixing member 70 forms an outer circumferential surface with a screw line, and the fixing groove 34a forms an inner circumferential surface with a screw line so as to fix the gap without connecting the ondol panel.

In addition, the mounting protrusion 34 may be manufactured to be assembled in a snap-fit method.

As shown in FIG. 21, the copper tube 80 is inserted into the upper and lower bodies 37 and 38 to prevent leakage of the heating fluid and further increase heating efficiency, thereby ultrasonically fusion. Combine with each other.

As shown in (a) of FIG. 22, the fourth ondol panel 40 having a female structure in which the mounting portion 32 connected to the male structure of the other ondol panel has a female structure has one side long and one side short '. A flow path 1 having a ┎ 'shape is formed, and mounting portions 32 are formed at both ends of the flow path 1, and the mounting portion 32 of the fourth ondol panel 40 is connected to the flow path 1. A mounting groove 36 having a connection groove 35 and a fixing hole 36a penetrating to both sides of the female connection groove 35 to an upper surface of the fourth ondol panel 40 and into which the fixing member 70 is inserted. ) And integrally injection molding.

As shown in (b) of FIG. 22, the insert injection is inserted into the flow path 1 of the fourth ondol panel 40 by inserting a copper tube 80 which further improves heating efficiency while preventing leakage of the heating fluid. Form.

As shown in FIG. 23, the fourth ondol panel 40 includes upper and lower bodies 37 and 38 to correspond to each other. The upper and lower bodies 37 and 38 are coupled to each other by ultrasonic welding.

Here, the fixing member 70 forms the outer circumferential surface with a screw line, and the fixing hole 36a forms the inner circumferential surface with a screw line so as to fix the gap so that the gap does not open during each ondol panel connection assembly.

In addition, the mounting groove 36 may be manufactured to be assembled in a snap-fit method.

As shown in Figure 24, by inserting a copper tube (80) to increase the heating efficiency while preventing the leakage of the heating fluid inside the flow path (1) of the upper body, the lower body (37, 38) by ultrasonic welding method Combine with each other.

As shown in FIG. 25, the fourth ondol panel 40 serves to change the flow direction of the circulated heating fluid and to send it to another ondol panel.

As shown in (a) of FIG. 26, the flow path 1 having a '┃' shape is formed in both sides in the longitudinal direction, and a female connection part 41 is formed at one end of the flow path 1, and the flow path (1) (42) is formed at the other end, respectively, the female connecting portion 41 of the fifth ondol panel 50 is assembled and connected to the water structure of the other ondol panel is a female connection groove (connected with the flow path 1 ( 45 and a mounting groove 46 having a fixing hole 46a through which the fixing member 70 is inserted and penetrating to the upper surface of the fifth ondol panel 50 on both sides of the female connecting groove 45.

The male connecting portion 52 of the fifth ondol panel 50, which is connected and assembled with the female structure of another ondol panel, is connected to the flow path 1 and has an O-ring groove 53a in which an O-ring 60 is fitted on an outer circumferential surface thereof. It consists of a male connecting pipe 53 and a mounting protrusion 54 having a fixing groove 54a into which the fixing member 70 is inserted into both sides of the male connecting pipe 53, thereby integrally injection molding.

As shown in FIG. 26 (b), the insert injection unit is inserted into the flow path 1 of the fifth ondol panel 20 by inserting a copper tube 80 which further improves heating efficiency while preventing leakage of the heating fluid. Form.

Here, the fifth ondol panel 50 may be made of FRP or polypropylene.

In addition, to reduce the weight in the line that does not harm the configuration of the fifth ondol panel 50 can be produced by forming a square or circular groove.

As shown in FIG. 27, the fifth ondol panel 50 includes upper and lower bodies 47 and 48 to correspond to each other. The upper and lower bodies 47 and 48 are coupled to each other by ultrasonic welding.

Here, the fixing member 70 is formed with an outer circumferential surface by a screw line, and the fixing hole 46a and the fixing groove 44a are formed with a screw line so as to fix the gap so as not to open a gap when assembling each ondol panel. do.

In addition, the mounting groove 46 and the mounting protrusion 44 may be manufactured to be assembled in a snap-fit method.

As shown in Figure 28, by inserting a copper tube (80) to increase the heating efficiency while preventing the leakage of the heating fluid inside the flow path (1) of the upper body, the lower body (47, 48) by ultrasonic welding method Combine with each other.

As shown in FIG. 29 (a), the flow path 1 formed inside the fifth ondol panel 50 also serves to send the circulated heating fluid to the boiler.

Here, the fifth ondol panel 50 may be supplied with a heating fluid from the boiler according to the flow direction of the heating fluid.

As shown in (b) of FIG. 29, the flow direction of the heating fluid is reversed to serve to circulate.

As shown in Figure 30, in the assembly method of the prefabricated ondol panel for heating,

The second under-floor heating panel (20) '┃┃' shaped flow path (1), one each formed on the third floor heating panel (30), 'U' shaped flow path (1) one to the number of connection 12 respectively formed mounting portion ( 22 is connected to each other, and the first ondol panel 10 has a '┏'-shaped flow path in the female connection portion 11 formed at the other end of the'┃┃'-shaped flow path 1 of the second ondol panel 20, respectively. a first step of (1) one end mounting portion formed in (2) and the third connect one of the floor heating panel (30), 'U' shaped flow path (1), each one formed compartment 22 to the assembly,

Except for the first ondol panel 10 in the first step, according to the size of the room, the third ondol panel 30 ' Ｕ ' at both ends of the '┃┃'-shaped flow path 1 of the second ondol panel 20. Repeatedly connected to each of the flow path (1) of the shape, at the end of the size of the room on the one end of the second ondol panel 20 '┃┃' shaped flow path (1) formed in the female connector (11) A second step of assembling and assembling one mounting portion 32 formed at one end of the fourth ondol panel 40 on one end of the flow path 1 having a long one and a short '┎' shape,

In the second step, the fourth ondol panel 40 has one long side and one short '┎'-shaped flow path 1 in the mounting portion 32 formed at the other end of the fifth ondol panel 50. 1) Connecting and assembling the female connecting portion 41 formed at one end, and the heating prefabricated in the third step of repeatedly connecting and assembling the fifth 'dol' 50 '┃' shape to the end of the size of the room Ondol panels can be assembled.

Here, at least one second ondol panel 20 may be repeatedly assembled and assembled.

In addition, since the second ondol panel 20 is repeatedly assembled between the third ondol panels 30 formed on both sides, the construction time is reduced and the cost is reduced.

In addition, since the flow direction of the heating fluid varies according to the position of the boiler, the first ondol panel 10 may serve as an inlet or outlet, and likewise, the fifth ondol panel 50 may also serve as an inlet or outlet. Can be.

As shown in Figure 31, in the assembly method of the prefabricated ondol panel for heating,

The third floor heating panel (30), 'U' shaped flow path (1) one can in formed on the fifth floor heating panel (50) '┃' shaped flow path (1), one end of the mounting portions 22 formed respectively connecting portion 42 Connecting to each other, and the third ondol panel 30 has a female connection part formed at the other end of the flow path 1 having a '온' shape in the fifth ondol panel 50 respectively connected to a ' Ｕ ' shaped flow path ( 41) of the first under-floor heating panel (10) '┏' channel of the shape (1) one end mounting portion (2 formed on) of the third floor heating panel (30), 'U' shaped flow path (1), each formed mounting portion at one end in A first step of assembling and assembling one of each of (22),

Except for the first ondol panel 10 in the first step, according to the size of the room, the third ondol panel 30 ' Ｕ ' shape on both ends of the '┃'-shaped flow path 1 of the fifth ondol panel 50. Each of the flow paths 1 are repeatedly assembled, and the fourth ondol panel is connected to the female connection part 41 formed at one end of the fifth 'Ondol panel 50'-shaped flow path 1 at the end of the size of the room. (40) a second step of assembling and assembling one mounting portion 32 formed at one end of one of the long and one of the short '┎'-shaped flow paths 1,

In the second step, the fourth ondol panel 40 has one long side and one short '┎'-shaped flow path 1 in the mounting portion 32 formed at the other end of the fifth ondol panel 50. 1) Connecting and assembling the female connecting portion 41 formed at one end, and the heating prefabricated in the third step of repeatedly connecting and assembling the fifth 'dol' 50 '┃' shape to the end of the size of the room Ondol panels can be assembled.

Here, at least one or more fifth ondol panels 50 connected and assembled between the third ondol panels 30 may be repeatedly assembled.

In addition, since the second ondol panel 20 is removed and assembled, workers can easily transport and work, thereby obtaining the speed of work.

In addition, since the flow direction of the heating fluid varies according to the position of the boiler, the first ondol panel 10 may serve as an inlet or an outlet, and likewise, the fifth onboard panel 40 is assembled and connected to the fourth ondol panel 40. Ondol panel 50 may also serve as an inlet or outlet.

As shown in Figure 32, in the assembly method of the prefabricated ondol panel for heating,

The second under-floor heating panel (20) '┃┃' shaped flow path (1), one each formed on the third floor heating panel (30), 'U' shaped flow path (1) one to the number of connection 12 respectively formed mounting portion ( 22 is connected to each other, and the second ondol panel 20 has a '┏'-shaped flow path in the female connection portion 11 formed at the other end of the'┃┃'-shaped flow path 1, respectively. and 1) one end mounting portion (formed in the second) and the third connect one of the floor heating panel (30), 'U' shaped flow path (1), each one formed compartment 22 to the first stage of assembly,

In the first stage to one end of the third floor heating panel (30), 'U' shaped flow path (1) one wherein the remaining mounting portion 22 formed on the five-floor heating panel (50) '┃' shaped flow path (1) connection assembly of the formed female connecting portion 41 and the fifth floor heating panel (50) '┃' shaped flow path (1), the third floor heating panel (30), 'U' shaped channel of the number of connection portion 42 formed at the other end (1) a second step of connecting and assembling one of the mounting portions 22 formed at one end thereof,

In the second step, the third ondol panel 30 'Ｕ'- shaped flow paths 1 are repeatedly connected and assembled at both ends of the fifth ondol panel 50'┃'-shaped flow path 1 according to the size of the room. One end of the fourth ondol panel 40 is long and one end of the fourth ondol panel 40 has a female connection portion 41 formed at one end of the fifth ondol panel 50 at the end of the size of the room. A third step of assembling and assembling the mounting portion 32 formed at one end of the channel 1,

In the third step, the fifth ondol panel 50 has a '┃'-shaped flow path in a mounting portion 32 formed at the other end of the fourth ondol panel 40 at one end of the fourth ondol panel 40. 1) Connecting and assembling the female connecting portion 41 formed at one end, the heating prefabricated in the fourth step of repeatedly connecting and assembling the fifth 'dol' 50 ')' shaped passage until the end of the size of the room Ondol panels can be assembled.

Here, at least one or more fifth ondol panels 50 connected and assembled between the third ondol panels 30 may be repeatedly assembled, and at the same time, the first ondol panel 10 and the third ondol panel 30 may be assembled. At least one second ondol panel 20 that is connected and assembled between the two may also be repeatedly assembled.

In addition, since the second ondol panel 20 and the fifth ondol panel 50 are assembled between the third ondol panels 30 in a relatively small room in a living space, convenience of work can be obtained. .

In addition, since the flow direction of the heating fluid varies according to the position of the boiler, the first ondol panel 10 may serve as an inlet or an outlet, and likewise, the fifth onboard panel 40 is assembled and connected to the fourth ondol panel 40. Ondol panel 50 may also serve as an inlet or outlet.

As shown in Figure 33, in the assembly method of the prefabricated ondol panel for heating,

The second under-floor heating panel (20) '┃┃' shaped flow path (1), one each formed on the third floor heating panel (30), 'U' shaped flow path (1) one to the number of connection 12 respectively formed mounting portion ( 22) and the second ondol panel 20 has one end of the fourth ondol panel 40 long and one side of the female connecting portion 11 formed at the other end of the '1'-shaped flow path 1, respectively. ┎ connect one of the "flow path of the shape (1) one end mounting portion 32 and the third floor heating panel 30 is formed in a 'U' shape of the flow path (1) once each formed mounting portion 22 to the assembled first step of Wow,

In the first stage to one end of the third floor heating panel (30), 'U' shaped flow path (1) one wherein the remaining mounting portion 22 formed on the five-floor heating panel (50) '┃' shaped flow path (1) connection assembly of the formed female connecting portion 41 and the fifth floor heating panel (50) '┃' shaped flow path (1), the third floor heating panel (30), 'U' shaped channel of the number of connection portion 42 formed at the other end (1) a second step of connecting and assembling one of the mounting portions 22 formed at one end thereof,

In the second step, the third ondol panel 30 'Ｕ'- shaped flow paths 1 are repeatedly connected and assembled at both ends of the fifth ondol panel 50'┃'-shaped flow path 1 according to the size of the room. At the end of the size of the room, the fifth ondol panel 50 has a '┏' shaped flow path 1 in the female connector 41 formed at one end of the '1' shaped flow path 1. A third step of connecting and assembling the mounting portion 2 formed at one end thereof;

In the first step, the fifth ondol panel 50 has a '┃'-shaped flow path in the mounting portion 32 formed at the other end of the first one of the fourth ondol panel 40 and the short one of the short' 온 '-shaped flow paths 1. 1) Connecting and assembling the female connecting portion 41 formed at one end, the heating prefabricated in the fourth step of repeatedly connecting and assembling the fifth 'dol' 50 ')' shaped passage until the end of the size of the room I can assemble an ondol panel,

Here, at least one or more fifth ondol panels 50 connected and assembled between the third ondol panels 30 may be repeatedly assembled, and at the same time, the fourth ondol panel 40 and the third ondol panel 30 may be assembled. At least one second ondol panel 20 that is connected and assembled between the two may also be repeatedly assembled.

In addition, since the second size of the ondol panel 50 is not connected to the second ondol panel 50 to be assembled between the third ondol panel 30 at the end of the size of the room, assembling work time during construction It has the effect of reducing it.

In addition, since the flow direction of the heating fluid varies according to the position of the boiler, the first ondol panel 10 may serve as an inlet or outlet, and likewise, the fifth ondol panel 50 may also serve as an inlet or outlet. Can be.

Therefore, the present invention uses the first ondol panel 10, the second ondol panel 20, the third ondol panel 30, the fourth ondol panel 40, the fifth ondol panel 50, Even if the size is not standardized, it can be assembled to fit the size of the room.

In addition, anyone can be easily assembled and assembled even if the skilled worker, since the efficiency of the work is maximized during construction, it can be said that the effect of reducing the cost accordingly.

In addition, since it can be easily injected and manufactured, not only the construction cost of the ondol can be lowered, but also the convenience of transportation to the work site can be obtained.

In the above, the present invention has been illustrated and described with reference to certain preferred embodiments, but the present invention is not limited to the above-described embodiments, and the present invention is not limited to the spirit of the present invention. Various changes and modifications can be made by those who have

1: Euro 2, 22, 32: Mounting part
3, 13, 23, 33, 43: male connector 7, 17, 27, 37, 47: upper body
8, 18, 28, 38, 48: lower body 11, 41: female connection
12, 42: male connection portion 3a, 13a, 23a, 33a, 43a: O-ring groove
4, 14, 24, 34, 44: mounting protrusions 4a, 14a, 24a, 34a, 44a: fixing groove
5, 15, 25, 35, 45: female connection groove 6, 16, 26, 36, 46: mounting groove
6a, 16a, 26a, 36a, 46a: fixing hole 10: first ondol panel
20: second ondol panel 30: third ondol panel
40: fourth ondol panel 50: fifth ondol panel
60: O-ring 70: fixing member
80: Dongguan

Claims (37)

In the prefabricated ondol panel for heating is installed on the floor indoors and receives heating fluid from the boiler,
A prefabricated ondol panel for heating comprising a first ondol panel 10 having a '유로' shape formed therein and having mounting portions 2 formed at both ends of the flow passage 1. The method of claim 1,
The mounting portion 2 of the first ondol panel 10 is connected to the flow path 1, the male connecting pipe 3 is provided with an O-ring groove (3a) is fitted in the outer peripheral surface of the O-ring 60, the number Prefabricated ondol panel for heating, characterized in that consisting of a mounting projection (4) having a fixing groove (4a) is inserted into the both sides of the connection pipe (3). The method of claim 1,
The mounting portion 2 of the first ondol panel 10 penetrates to the upper surface of the first ondol panel 10 on both sides of the female connecting groove 5 and the female connecting groove 5, which are connected to the flow path 1. And a mounting groove 6 having a fixing hole 6a into which the fixing member 70 is inserted. The method according to claim 1 or 2 or 3,
The first ondol panel 10 is a prefabricated ondol panel for heating, characterized in that the injection molding. The method according to claim 1 or 2 or 3,
Prefabricated ondol panel for heating, characterized in that the insert injection molding by inserting the copper tube (80) in the flow path (1). The method according to claim 1 or 2 or 3,
Prefabricated ondol panel for heating, characterized in that the first ondol panel 10 is composed of an upper body, a lower body (7) (8) so as to correspond to each other, by coupling to each other by ultrasonic welding. The method according to claim 6,
Prefabricated ondol panel for heating, characterized in that the copper pipe (80) is inserted into the flow path (1) of the upper body, the lower body (7) (8), and mutually coupled by ultrasonic welding. In the prefabricated ondol panel for heating is installed on the floor indoors and receives heating fluid from the boiler,
The second ondol panel 20 in which the flow path 1 having a '양' shape is formed in the longitudinal direction on both sides thereof, and a female connection part and a male connection part 11 and 12 are formed at both ends of the flow path 1, respectively. Prefabricated ondol panel for heating comprising a. The method of claim 8,
The female connecting portion 11 of the second ondol panel 20 penetrates to the upper surface of the second ondol panel 20 on both sides of the female connecting groove 15 that is connected to the flow path 1 and the female connecting groove 15. And a mounting groove 16 having a fixing hole 16a into which the fixing member 70 is inserted,
The male connecting portion 12 of the second ondol panel 20 is connected to the flow path 1 and the male connecting pipe 13 having an O-ring groove 13a fitted with an O-ring 60 on an outer circumferential surface thereof, and the male Prefabricated ondol panel for heating, characterized in that consisting of a mounting projection (14) having a fixing groove (14a) is inserted into the both sides of the connection pipe (13). The method according to claim 8 or 9,
The second ondol panel 20 is prefabricated ondol panel for heating, characterized in that the injection molding. The method according to claim 8 or 9,
Prefabricated ondol panel for heating, characterized in that the insert injection molding by inserting the copper tube (80) in the flow path (1). The method according to claim 8 or 9,
Prefabricated ondol panel for heating, characterized in that the second ondol panel 20 is configured to correspond to each other, the upper body, the lower body (17) (18), by mutually coupling in an ultrasonic welding method. The method of claim 12,
The upper and lower bodies (17) (18) by inserting the copper tube (80) inside the flow path (1), prefabricated ondol panel for heating, characterized in that they are mutually coupled by ultrasonic welding. In the prefabricated ondol panel for heating is installed on the floor indoors and receives heating fluid from the boiler,
A prefabricated ondol panel for heating comprising a third ondol panel 30 having a ' Ｕ ' shape formed therein and having mounting portions 22 formed on the same surface at both ends of the flow passage 1. The method of claim 14,
The mounting portion 22 of the third ondol panel 30 penetrates to the upper surface of the third ondol panel 30 on both sides of the female connecting groove 25 and the female connecting groove 25 formed to be connected to the flow path 1. And a mounting groove 26 having a fixing hole 26a into which the fixing member 70 is inserted. The method of claim 14,
The mounting portion 22 of the third ondol panel 30 has a male connecting pipe 23 connected to the flow path 1 and a fixing groove into which the fixing member 70 is inserted into both sides of the male connecting pipe 23. Prefabricated ondol panel for heating, characterized in that it comprises a mounting protrusion 24 provided with (24a). The method according to any one of claims 14 or 15 or 16,
The third ondol panel 30 is a prefabricated ondol panel for heating, characterized in that the injection molding. The method according to any one of claims 14 or 15 or 16,
Prefabricated ondol panel for heating, characterized in that the insert injection molding by inserting the copper tube (80) in the passage (1). The method according to any one of claims 14 or 15 or 16,
The third ondol panel 30 is configured to correspond to the upper body, the lower body (27) (28), prefabricated ondol panel for heating, characterized in that the mutual coupling by ultrasonic welding. The method of claim 19,
The upper body and the lower body 27, 28, the copper pipe 80 is inserted into the flow path (1), prefabricated ondol panel for heating, characterized in that the mutual coupling by ultrasonic welding. In the prefabricated ondol panel for heating is installed on the floor indoors and receives heating fluid from the boiler,
A prefabricated ondol panel for heating comprising a fourth ondol panel 40 having a long one side and a short '┎' shape in one side and a mounting portion 32 formed at both ends of the flow path 1. . The method of claim 21,
The mounting portion 32 of the fourth ondol panel 40 is a water connecting pipe 33 having an O-ring groove 33a in which an O-ring 60 is fitted on an outer circumferential surface of the flow path 1, and the water connecting pipe 33. (33) A prefabricated ondol panel for heating, comprising a mounting protrusion 34 having a fixing groove 34a into which the fixing member 70 is inserted at both sides. The method of claim 21,
The mounting portion 32 of the fourth ondol panel 40 penetrates to the upper surface of the fourth ondol panel 40 on both sides of the female connecting groove 35 and the female connecting groove 35, which are connected to the flow path 1. And a mounting groove 36 having a fixing hole 36a into which the fixing member 70 is inserted. The method according to any one of claims 21 or 22 or 23,
The fourth ondol panel 40 is a prefabricated ondol panel for heating, characterized in that the injection molding. The method according to any one of claims 21 or 22 or 23,
Prefabricated ondol panel for heating, characterized in that the insert injection molding by inserting the copper tube (80) in the passage (1). The method according to any one of claims 21 or 22 or 23,
Prefabricated ondol panel for heating, characterized in that the fourth ondol panel 40 is configured to correspond to each other, the upper body, the lower body (37) (38), so as to combine with each other by ultrasonic welding. The method of claim 26,
The upper body and the lower body (37) (38) by inserting the copper tube (80) inside the flow path (1), prefabricated ondol panel for heating, characterized in that the mutual coupling by ultrasonic welding. In the prefabricated ondol panel for heating is installed on the floor indoors and receives heating fluid from the boiler,
A flow path 1 having a '┃' shape therein is formed in the longitudinal direction, and a female connection part 41 is formed at one end of the flow path 1, and a male connection part 42 is formed at the other end of the flow path 1. Prefabricated ondol panel for heating comprising 5 ondol panels (50). 29. The method of claim 28,
The female connecting portion 41 of the fifth ondol panel 50 penetrates to the upper surface of the fifth ondol panel 50 on both sides of the female connecting groove 45 formed to be connected to the flow path 1 and the female connecting groove 45. And a mounting groove 46 having a fixing hole 46a into which the fixing member 70 is inserted,
The male connecting portion 42 of the fifth ondol panel 50 is connected to the flow path 1 and the male connecting pipe 43 having an O-ring groove 43a to which the O-ring 60 is fitted on the outer circumferential surface thereof, and the male Prefabricated ondol panel for heating, characterized in that consisting of a mounting projection 44 is provided with a fixing groove (44a) is inserted into the both sides of the connection pipe (43). The method of claim 28 or 29,
The fifth ondol panel 50 is a prefabricated retaining panel and assembly method for heating, characterized in that the injection molding. The method of claim 28 or 29,
Prefabricated ondol panel for heating, characterized in that the insert injection molding by inserting the copper tube (80) in the passage (1). The method of claim 28 or 29,
The fifth ondol panel 50 is composed of upper and lower bodies 47, 48 corresponding to each other, prefabricated ondol panel for heating, characterized in that the mutual coupling in an ultrasonic welding method. 33. The method of claim 32,
The upper body and the lower body 47, 48, prefabricated ondol panel for heating, characterized in that the copper tube 80 is inserted into the flow path (1), and mutually coupled by ultrasonic welding. A first ondol panel 10 having a '┏' shape formed therein and having a mounting portion 2 formed at both ends of the flow path 1,
The flow path 1 of the '┃┃' shape is formed in both sides in the longitudinal direction, the female connection portion 11 is formed at one end of the flow path 1, respectively, the male connection portion 12 at the other end of the flow path (1) The second ondol panel 20 is formed, respectively,
A third ondol panel 30 in which a flow path 1 having a ' Ｕ ' shape is formed, and mounting portions 22 are formed on the same surface at both ends of the flow path 1,
A fourth ondol panel 40 having a long one side and a short '┎' shape in one side, and a mounting portion 32 formed at both ends of the channel 1,
The flow path 1 having a '┃' shape therein is formed in the longitudinal direction, the female connection portion 41 is formed at one end of the flow path 1, and the male connection part 42 is formed at the other end of the flow path 1. In the assembling method of the prefabricated ondol panel for heating to be assembled and assembled using the fifth ondol panel 50,
The second under-floor heating panel (20) '┃┃' shaped flow path (1), one each formed on the third floor heating panel (30), 'U' shaped flow path (1) one to the number of connection 12 respectively formed mounting portion ( 22 is connected to each other, and the first ondol panel 10 has a '┏'-shaped flow path in the female connection portion 11 formed at the other end of the'┃┃'-shaped flow path 1 of the second ondol panel 20, respectively. a first step of (1) one end mounting portion formed in (2) and the third connect one of the floor heating panel (30), 'U' shaped flow path (1), each one formed compartment 22 to the assembly,
Except for the first ondol panel 10 in the first step, according to the size of the room, the third ondol panel 30 ' Ｕ ' at both ends of the '┃┃'-shaped flow path 1 of the second ondol panel 20. Repeatedly connected to each of the flow path (1) of the shape, at the end of the size of the room on the one end of the second ondol panel 20 '┃┃' shaped flow path (1) formed in the female connector (11) A second step of assembling and assembling one mounting portion 32 formed at one end of the fourth ondol panel 40 on one end of the flow path 1 having a long one and a short '┎' shape,
In the second step, the fourth ondol panel 40 has one long side and one short '┎'-shaped flow path 1 in the mounting portion 32 formed at the other end of the fifth ondol panel 50. 1) to connect and assemble the female connecting portion 41 formed at one end, and the third step of repeatedly assembling the fifth 'ondol panel 50' ┃ 'shape to the end of the size of the room Assembly method of prefabricated ondol panel for heating. A first ondol panel 10 having a '┏' shape formed therein and having a mounting portion 2 formed at both ends of the flow path 1,
A third ondol panel 30 in which a flow path 1 having a ' Ｕ ' shape is formed, and mounting portions 22 are formed on the same surface at both ends of the flow path 1,
A fourth ondol panel 40 having a long one side and a short '┎' shape in one side, and a mounting portion 32 formed at both ends of the channel 1,
The flow path 1 having a '┃' shape therein is formed in the longitudinal direction, the female connection portion 41 is formed at one end of the flow path 1, and the male connection part 42 is formed at the other end of the flow path 1. In the assembling method of the prefabricated ondol panel for heating to be assembled and assembled using the fifth ondol panel 50,
The third floor heating panel (30), 'U' shaped flow path (1) one can in formed on the fifth floor heating panel (50) '┃' shaped flow path (1), one end of the mounting portions 22 formed respectively connecting portion 42 Connecting to each other, and the third ondol panel 30 has a female connection part formed at the other end of the flow path 1 having a '온' shape in the fifth ondol panel 50 respectively connected to a ' Ｕ ' shaped flow path ( 41) of the first under-floor heating panel (10) '┏' channel of the shape (1) one end mounting portion (2 formed on) of the third floor heating panel (30), 'U' shaped flow path (1), each formed mounting portion at one end in A first step of assembling and assembling one of each of (22),
Except for the first ondol panel 10 in the first step, according to the size of the room, the third ondol panel 30 ' Ｕ ' shape on both ends of the '┃'-shaped flow path 1 of the fifth ondol panel 50. Each of the flow paths 1 are repeatedly assembled, and the fourth ondol panel is connected to the female connection part 41 formed at one end of the fifth 'Ondol panel 50'-shaped flow path 1 at the end of the size of the room. (40) a second step of assembling and assembling one mounting portion 32 formed at one end of one of the long and one of the short '┎'-shaped flow paths 1,
In the second step, the fourth ondol panel 40 has one long side and one short '┎'-shaped flow path 1 in the mounting portion 32 formed at the other end of the fifth ondol panel 50. 1) to connect and assemble the female connecting portion 41 formed at one end, and the third step of repeatedly assembling the fifth 'ondol panel 50' ┃ 'shape to the end of the size of the room Assembly method of prefabricated ondol panel for heating. A first ondol panel 10 having a '┏' shape formed therein and having a mounting portion 2 formed at both ends of the flow path 1,
The second ondol panel 20 in which the flow path 1 having a '양' shape is formed in the longitudinal direction on both sides thereof, and a female connection part and a male connection part 11 and 12 are formed at both ends of the flow path 1, respectively. and,
A third ondol panel 30 in which a flow path 1 having a ' Ｕ ' shape is formed, and mounting portions 22 are formed on the same surface at both ends of the flow path 1,
A fourth ondol panel 40 having a long one side and a short '┎' shape in one side, and a mounting portion 32 formed at both ends of the channel 1,
The flow path 1 having a '┃' shape therein is formed in the longitudinal direction, the female connection portion 41 is formed at one end of the flow path 1, and the male connection part 42 is formed at the other end of the flow path 1. In the assembling method of the prefabricated ondol panel for heating to be assembled and assembled using the fifth ondol panel 50,
The second under-floor heating panel (20) '┃┃' shaped flow path (1), one each formed on the third floor heating panel (30), 'U' shaped flow path (1) one to the number of connection 12 respectively formed mounting portion ( 22 is connected to each other, and the second ondol panel 20 has a '┏'-shaped flow path in the female connection portion 11 formed at the other end of the'┃┃'-shaped flow path 1, respectively. and 1) one end mounting portion (formed in the second) and the third connect one of the floor heating panel (30), 'U' shaped flow path (1), each one formed compartment 22 to the first stage of assembly,
In the first stage to one end of the third floor heating panel (30), 'U' shaped flow path (1) one wherein the remaining mounting portion 22 formed on the five-floor heating panel (50) '┃' shaped flow path (1) connection assembly of the formed female connecting portion 41 and the fifth floor heating panel (50) '┃' shaped flow path (1), the third floor heating panel (30), 'U' shaped channel of the number of connection portion 42 formed at the other end (1) a second step of connecting and assembling one of the mounting portions 22 formed at one end thereof,
In the second step, the third ondol panel 30 'Ｕ'- shaped flow paths 1 are repeatedly connected and assembled at both ends of the fifth ondol panel 50'┃'-shaped flow path 1 according to the size of the room. One end of the fourth ondol panel 40 is long and one end of the fourth ondol panel 40 has a female connection portion 41 formed at one end of the fifth ondol panel 50 at the end of the size of the room. A third step of assembling and assembling the mounting portion 32 formed at one end of the channel 1,
In the third step, the fifth ondol panel 50 has a '┃'-shaped flow path in a mounting portion 32 formed at the other end of the fourth ondol panel 40 at one end of the fourth ondol panel 40. 1) to connect and assemble the female connecting portion 41 formed at one end, and the fourth step of repeatedly assembling the fifth 'ondol panel 50'┃'-shaped passage to the end of the size of the room Assembly method of prefabricated ondol panel for heating. A first ondol panel 10 having a '┏' shape formed therein and having a mounting portion 2 formed at both ends of the flow path 1,
The flow path 1 of the '┃┃' shape is formed in both sides in the longitudinal direction, the female connection portion 11 is formed at one end of the flow path 1, respectively, the male connection portion 12 at the other end of the flow path (1) The second ondol panel 20 is formed, respectively,
A third ondol panel 30 in which a flow path 1 having a ' Ｕ ' shape is formed, and mounting portions 22 are formed on the same surface at both ends of the flow path 1,
A fourth ondol panel 40 having a long one side and a short '┎' shape in one side, and a mounting portion 32 formed at both ends of the channel 1,
The flow path 1 having a '┃' shape therein is formed in the longitudinal direction, the female connection portion 41 is formed at one end of the flow path 1, and the male connection part 42 is formed at the other end of the flow path 1. In the assembling method of the prefabricated ondol panel for heating to be assembled and assembled using the fifth ondol panel 50,
The second under-floor heating panel (20) '┃┃' shaped flow path (1), one each formed on the third floor heating panel (30), 'U' shaped flow path (1) one to the number of connection 12 respectively formed mounting portion ( 22) and the second ondol panel 20 has one end of the fourth ondol panel 40 long and one side of the female connecting portion 11 formed at the other end of the '1'-shaped flow path 1, respectively. ┎ connect one of the "flow path of the shape (1) one end mounting portion 32 and the third floor heating panel 30 is formed in a 'U' shape of the flow path (1) once each formed mounting portion 22 to the assembled first step of Wow,
In the first stage to one end of the third floor heating panel (30), 'U' shaped flow path (1) one wherein the remaining mounting portion 22 formed on the five-floor heating panel (50) '┃' shaped flow path (1) connection assembly of the formed female connecting portion 41 and the fifth floor heating panel (50) '┃' shaped flow path (1), the third floor heating panel (30), 'U' shaped channel of the number of connection portion 42 formed at the other end (1) a second step of connecting and assembling one of the mounting portions 22 formed at one end thereof,
In the second step, the third ondol panel 30 'Ｕ'- shaped flow paths 1 are repeatedly connected and assembled at both ends of the fifth ondol panel 50'┃'-shaped flow path 1 according to the size of the room. At the end of the size of the room, the fifth ondol panel 50 has a '┏' shaped flow path 1 in the female connector 41 formed at one end of the '1' shaped flow path 1. A third step of connecting and assembling the mounting portion 2 formed at one end thereof;
In the first step, the fifth ondol panel 50 has a '┃'-shaped flow path in the mounting portion 32 formed at the other end of the first one of the fourth ondol panel 40 and the short one of the short' 온 '-shaped flow paths 1. 1) to connect and assemble the female connecting portion 41 formed at one end, and the fourth step of repeatedly assembling the fifth 'ondol panel 50'┃'-shaped passage to the end of the size of the room Assembly method of prefabricated ondol panel for heating.

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