KR102474422B1 - Anchoring element for radiating pipe used for dry-hybrid heating system to prevent heating pipe's seperation - Google Patents

Abstract

The present invention relates to a radiating pipe anchoring member for a dry-hybrid heating system to prevent separation of a radiating pipe, which can prevent separation of a hot water radiating pipe or an electric radiating pipe from an insulation board during construction or when an external force is generated due to an earthquake or shock and, more specifically, to a radiating pipe anchoring member for a dry-hybrid heating system to prevent separation of a radiating pipe. The radiating pipe anchoring member for a dry-hybrid heating system comprises: a fixed pipe which is fitted on a first groove formed between protrusion parts disposed at the edge of each virtual space of an insulation board and has an open side formed thereon to fit a hot water radiating pipe or an electric radiating pipe through the open entrance; holding parts which are formed vertically on both sides of the open entrance of the fixed pipe to hold the hot water radiating pipe or the electric radiating pipe fitted into the fixed pipe; and contact parts formed horizontally on sides of the holding parts to make close contact with the upper surfaces of the protrusion parts. The surfaces, facing each other, of the protrusion parts disposed at the edge of each virtual space have a holding protrusion on which the fixed pipe fitted on the first groove is held.

Description

Heating pipe fixing member for dry composite heating system that prevents separation of heat pipe {Anchoring element for radiating pipe used for dry-hybrid heating system to prevent heating pipe's separation}

The present invention relates to a heat sink fixing member for a dry combined heating system, and more particularly, to a heat sink fixing member for a dry combined heating system that fixes a hot water heat sink or an electric heat sink to an insulating board installed on the floor of a building.

In general, there are a wet method and a dry method for constructing floor heating.

Here, the wet method is a method of constructing by laying an insulation board on the floor, piping a hot water pipe thereon, and then pouring concrete mortar, and the dry method is a method of constructing a floor board, wood, stone, or metal and synthetic resin material instead of concrete mortar. how to use

In this regard, Patent Document 1 uses a square plate made of a synthetic resin material by injection molding or press extrusion molding as a base plate, and the upper surface of the base plate has a straight shape having a height and width to accommodate a hot water radiator. Several lines of pipe grooves are formed at regular intervals in both vertical and horizontal directions, and cylindrical pipe grooves, semi-circular pipe grooves, and 1/4 arc-shaped pipe grooves are placed at the center, all four sides, and four corners, respectively, at intervals between hot water radiation pipe arrangements. In forming a four-way continuous assembly type pipe panel having dozens of protruding support members formed by; Among the configurations of dozens of protruding support members provided on the upper surface of the pipe panel, a circular group support member formed with the diameter of the same standard as the arrangement interval of the unit hot water heat radiation pipe within the standard having the same area as the existing pipe panels , while dividing it into 3 equal parts in a square shape in both directions in the horizontal and vertical directions to form a circular group support member of 9 pieces, and further providing a straight pipe groove of 2 lines each horizontally and vertically on the divided line, and the equal division A multi-purpose piping panel for ondol was provided, characterized in that the 9 pieces of circular group support members were formed in a shell shape open to the bottom of the bottom plate.

However, in the case of Patent Document 1, there is a concern that the hot water heat radiation pipe may be separated from the pipe groove during construction or when an external force is generated due to an earthquake, shock, or the like.

That is, there is a concern that the height between the hot water heat dissipation pipes may occur.

In other words, since the installation position of the hot water radiating pipe is not maintained, there is a concern that heating efficiency may be lowered as a temperature deviation occurs due to the occurrence of height.

Patent Document 1: Domestic Patent Registration No. 10-1188201 (registered on September 27, 2012)

Accordingly, an object of the present invention is to provide a heat radiation pipe fixing member for a dry composite heating system that prevents a hot water heat radiation pipe or an electric heat radiation pipe from escaping from an insulation board when an external force is generated due to an earthquake, impact, or the like during construction.

In order to achieve the above object, the present invention, a plurality of adjacently installed on the floor surface of the building, a grid-shaped first groove is formed at regular intervals on one side to form a plurality of protrusions, N x N protrusions Each is divided into virtual spaces, and a circular second groove is formed based on the center of the virtual space, and the second groove overlaps the first groove dividing the virtual space and the adjacent second groove in width, and the virtual space a heat insulation plate having a third circular groove formed at the center of the and a fourth circular groove formed between the second and third grooves based on the center of the virtual space; In a dry combined heating system including hot water radiating pipes or electric radiating pipes fitted into the first, second, third, and fourth grooves, the first grooves are inserted into the first grooves formed between the protrusions disposed at the corners of each virtual space. In the heat radiating pipe fixing member for a dry combined heating system that fixes a hot water radiating pipe or an electric radiating pipe, the radiating pipe fixing member for a dry combined heating system is fitted into a first groove, and one side is open to hot water through an open inlet. A fixed tube into which a heat radiation tube or an electric heat radiation tube is fitted; A holding portion formed vertically on both sides of the open inlet of the fixed pipe and engaging the hot water heat radiation pipe or the electric heat radiation pipe inserted into the fixed pipe; A contact portion formed horizontally on one side of the locking portion and in close contact with the upper surface of the protruding portion, and a locking jaw for engaging a fixed tube inserted into the first groove is formed on the facing surfaces of the protruding portions disposed at the corners of each virtual space. Provided is a heat radiation pipe fixing member for a dry composite heating system that prevents the escape of the heat radiation pipe.

The present invention has an effect that the hot water radiating pipe or the electric radiating pipe is more fixed to the first groove than in the prior art through the radiating pipe fixing member for the dry combined heating system.

In addition, there is an effect that the fixing tube is caught on the locking jaw.

In addition, there is an effect that the hot water radiating pipe or the electric radiating pipe inserted into the fixed pipe is caught on the hooking portion.

That is, during construction or when an external force is generated due to an earthquake or shock, it is effective to prevent the hot water radiating pipe or electric radiating pipe from escaping from the insulation plate, thereby preventing the hot water radiating pipe or electric radiating pipe from being raised or lowered.

In other words, by maintaining the installation position of the hot water radiating pipe or the electric radiating pipe, there is an effect of increasing heating efficiency by preventing temperature deviation caused by the occurrence of height.

In the present invention, since the width of the open inlet of the fixing pipe is narrowed by the obliquely formed hooking part, there is an effect that the hot water heat radiation pipe or the electric heat radiation pipe is more caught on the hooking part.

That is, there is an effect of further preventing the hot water radiating pipe or the electric radiating pipe from escaping from the insulation plate.

The present invention prevents the heat sink fixing member for a dry composite heating system from slipping or leaving the first groove because friction occurs between the contact protrusion of the fixing pipe and the first groove during construction or when an external force is generated due to an earthquake or shock. It works.

1 to 11 are installation state diagrams and partially enlarged views of a dry composite heating system to which a heat radiation pipe fixing member for a dry composite heating system according to an embodiment of the present invention is applied;
12 to 15 are detailed views of the insulation plate of the dry composite heating system to which the heat pipe fixing member for the dry composite heating system according to an embodiment of the present invention is applied;
16 is a use state diagram of a dry composite heating system to which a heat radiation pipe fixing member for a dry composite heating system according to an embodiment of the present invention is applied;
17 is an installation state diagram of a dry combined heating system to which a heat radiation tube fixing member for a dry combined heating system according to a modified example of an embodiment of the present invention is applied.

Accordingly, the embodiment of the present invention as described above will be described in detail based on the accompanying drawings.

As shown in FIGS. 1 to 17, the dry combined heating system 1000 according to the embodiment and modification of the present invention is installed on the floor surface 1a of the building 1, and the hot water heat radiation pipe 200 or It is used for heating by using the heat dissipated from the electric heat sink 210.

Here, the hot water radiating pipe 200 receives hot water from a boiler and generates heat to dissipate heat, and the electric radiating pipe 210 receives electricity from a power supply device to generate heat and dissipate heat.

In addition, the electric heat radiation tube 210 includes a metal pipe, a hot wire fixed inside the metal pipe, and an insulator filled inside the metal pipe, and is connected to a power supply device supplying electricity to the hot wire by a wire. do.

And, as shown in FIGS. 1 to 16, the dry composite heating system 1000 according to an embodiment of the present invention is installed adjacent to the floor surface 1a, and is installed on one side, that is, on the upper surface at regular intervals. A lattice-shaped first groove 110 is formed to form a plurality of protrusions 120, and the protrusions 120 are divided into N x N virtual spaces 130, with the center of the virtual space 130 as the reference A second groove 140 in a circular shape is formed, and the width of the second groove 140 overlaps with the first groove 110 dividing the virtual space 130 and the second groove 140 adjacent to each other. A third groove 150 in a circular shape is formed at the center of the virtual space 130, and a fourth groove 160 in a circular shape based on the center of the virtual space 130 is formed as second and third grooves. It is formed between (140) and (150), and the seating jaw 170 is formed long in the longitudinal direction on a part of the rim, and the rest of the rim is seated on the seating jaw 170 while the seating jaw 170 is fitted. The seating groove 171 is formed long in the longitudinal direction, and a plurality of fitting parts 180 are formed at predetermined intervals along the length direction of the seating jaw 170 to be connected to the adjacent protruding part 120, and the fitting part ( 180) is inserted into a plurality of fitting grooves 181 are formed at predetermined intervals along the length direction of the seating groove 171, and a portion adjacent to the seating groove 171 and a heat insulating plate 100 formed on the protrusion 120 are included. do.

Here, the insulating board 100 is made of EPP (expanded polystyrene) insulating material, and is manufactured by being molded by a precisely processed mold.

In addition, as shown in the drawing, the virtual space 130 divides the plurality of protrusions 120 of the insulating plate 100 by 4 x 4 units.

Here, the virtual space 130 positioned at the edge of the insulation board 100 is formed in a partially cut shape so that the insulation board 100 is connected to the adjacent insulation board 100, so that the number of protrusions 120 is reduced.

In addition, the seating protrusion 170 is formed on a portion of the edge of the insulating plate 100, that is, on a pair of adjacent side surfaces, and the seating groove 171 corresponds to the seating protrusion 170 and the rest of the edge of the insulation board 100. A portion, that is, formed on a pair of adjacent sides of the other side.

In addition, the fitting part 180 protrudes from the seating jaw 170 at regular intervals along the longitudinal direction of the seating jaw 170, and is connected to the adjacent protrusion 120.

In addition, the fitting groove 181 corresponds to the fitting portion 180, is formed in the seating groove 171 at regular intervals along the longitudinal direction of the seating groove 171, and a portion adjacent to the seating groove 171. That is, it is formed by extending from a portion of the bottom surface of the insulating board 100 and the protruding portion 120 .

In addition, the dry combined heating system 1000 includes a hot water radiating pipe 200 or an electric radiating pipe 210 inserted into the first, second, third, and fourth grooves 110, 140, 150, and 160. do.

In addition, the dry combined heating system 1000 includes a plurality of top plates 300 installed to cover the top of each insulating plate 100 .

Here, the top plate 300 is made of a metal material such as a copper plate or stainless steel having good heat conduction.

In addition, a finishing material such as linoleum, marble, wood, etc. is installed on the top of the top plate 300.

In addition, a lattice-shaped cut groove 190 is formed on one side of the insulating board 100 that comes into contact with the bottom surface 1a, that is, on the bottom surface of the insulating board 100.

Here, the cutting groove 190 is formed in a triangular cross section to facilitate cutting.

In addition, hooking parts 180a protrude from both sides of the outer surface of the fitting part 180, and hooking grooves 181a into which the hooking part 180a is fitted are formed on both sides of the fitting groove 181.

In addition, the dry complex heating system 1000 is inserted into the first groove 110 formed between the protrusions 120 disposed at the corners of each virtual space 130, and the hot water radiation pipe is inserted into the first groove 110. 200 or a heat radiation pipe fixing member 400 for a dry combined heating system for fixing the electric heat radiation pipe 210 is included.

Here, the heat radiation pipe fixing member 400 for the dry composite heating system is made of a material such as PC, copper plate, or stainless steel having good heat resistance and good heat conduction.

In addition, the heat radiation pipe fixing member 400 for the dry combined heating system is inserted into the first groove 110, and the hot water heat radiation pipe 200 or the electric heat radiation pipe 210 is forced through an open entrance with one side open. A fixed tube 410 that is fitted; A hanging portion 420 protruding vertically from both sides of the open inlet of the fixing pipe 410 and holding the hot water heat dissipating pipe 200 or electric heat dissipating pipe 210 inserted into the fixing pipe 410; A close contact part 430 is formed to protrude horizontally from one end of the hooking part 420 and adheres to the upper surface of the protruding part 120 .

In addition, the protruding portions 120 disposed at the corners of each of the virtual spaces 130 face each other with protruding protrusions 121 that engage the fixing tubes 410 inserted into the first grooves 110 .

And, as shown in FIG. 17, the locking part 420 of the dry combined heating system 1000 according to the modified example of the embodiment of the present invention narrows the width of the open inlet of the fixed pipe 410 ( 410) is formed obliquely protruding from both sides of the open inlet.

In addition, a contact protrusion 411 that adheres to the first groove 110 protrudes from the outer surface of the fixing tube 410 .

That is, the close protrusions 411 protrude from both sides of the fixing tube 410 .

Referring to the construction of the present invention configured as described above is as follows.

As shown in FIGS. 1 to 16 , in the dry combined heating system 1000 according to the embodiment of the present invention, a plurality of insulation plates 100 are installed adjacent to the floor surface 1a of the building 1 .

That is, while seating the seating groove 171 of the insulating plate 100 installed adjacent to the seating jaw 170 of the insulation board 100, the seating jaw 170 is inserted into the seating groove 171, and the insulation plate ( Insert the fitting part 180 of 100 into the fitting groove 181 of the insulation board 100 installed next to it.

Here, the engaging portion 180a of the fitting portion 180 is inserted into the engaging groove 181a of the fitting groove 181.

If the number of connected insulation boards 100 exceeds the area of the floor surface 1a of the building 1, the excess insulation boards 100 are cut through the cutting grooves 190.

In addition, the heat radiation pipe fixing member 400 for the dry combined heating system is inserted into the first groove 110 formed between the protrusions 120 disposed at the corners of each virtual space 130 .

Then, the fixing pipe 410 is inserted into the first groove 110 while being caught by the locking jaw 121, and the contact part 430 is in close contact with the upper surface of the protrusion part 120.

And, as shown in FIGS. 2 to 5, the hot water cooling pipe 200 or the electric cooling pipe 210 is formed in the first, second, third, and fourth grooves 110, 140, 150, and 160 respectively. Choose some of them and insert them.

That is, the straight water heat radiation pipe 200 selects and inserts some of the first and second grooves 110 and 140 so as to be piped at regular intervals to the plurality of connected insulation plates 100, and The hot water heat radiation pipe 200 having a curved shape connecting the hot water heat radiation pipe 200 is selected and inserted into some of the first and second grooves 110 and 140 respectively.

In addition, some of the first, second, third, and fourth grooves 110, 140, 150, and 160 are piped at regular intervals to the plurality of insulating plates 100 connected to the electric heat dissipation pipe 210 in the form of a straight line. select and insert

In addition, the hot water heat radiation pipe 200 or the electric heat radiation pipe 210 is forcibly inserted into the fixed pipe 410 through the open inlet of the fixed pipe 410 .

Then, the hot water heat radiation pipe 200 or the electric heat radiation pipe 210 inserted into the fixing pipe 410 is caught by the hanging part 420 .

Thus, the hot water heat radiation pipe 200 or the electric heat radiation pipe 210 is fixed to the first groove 110 through the heat radiation pipe fixing member 400 for the dry combined heating system.

In addition, a plurality of top plates 300 are installed to cover the top of each of the insulating plates 100 .

In addition, finishing materials such as linoleum, marble, and wood are installed on the top of the top plate 300 to finish.

Then, hot water is supplied to the hot water heat sink 200 or electricity is supplied to the electric heat sink 210 to generate heat.

Then, the heat is dissipated from the hot water heat radiation pipe 200 or the electric heat radiation pipe 210 and moves along the first, second, third, and fourth grooves 110, 140, 150, and 160.

Here, since the second, third, and fourth grooves 140, 150, and 160 are formed in a circular shape, the heat is transferred along the second, third, and fourth grooves 140, 150, and 160 to the insulating plate ( 100) moves smoothly.

That is, the heat rapidly heats the air in the first, second, third, and fourth grooves 110, 140, 150, and 160.

So, as the heat moves to each of the first, second, third, and fourth grooves 110, 140, 150, and 160 of the plurality of the insulating boards 100, the heat is sequentially transferred to the top plate 300 and the floor plate. , marble, wood, etc. are delivered to the heating.

Here, since the seating groove 171 is seated on the seating jaw 170, the seating jaw 170 is inserted and the fitting part 180 is inserted into the fitting groove 181, so heat is generated between the insulation plates 100. prevents it from escaping

In addition, the locking portion 180a is caught in the locking groove 181a when an external force such as an earthquake or shock is generated.

In addition, the fixing pipe 410 is caught on the locking jaw 121 when an external force is generated due to an earthquake, shock, or the like.

In addition, the hot water radiating pipe 200 or the electric radiating pipe 210 is caught by the hanging portion 420 when an external force is generated due to an earthquake, shock, or the like.

And, as shown in FIG. 17, in the dry combined heating system 1000 according to the modified example of the embodiment of the present invention, the fixing pipe 410 has a hanging part 420 protruding obliquely from both sides of the open inlet, the fixing pipe 410. The hot water radiating pipe 200 or the electric radiating pipe 210 inserted into 410 takes longer than in the embodiment.

Thus, when an external force such as an earthquake or shock is generated, the hot water radiating pipe 200 or the electric radiating pipe 210 is caught on the hooking part 420 more than in the embodiment.

In addition, since the close contact protrusion 411 of the fixing pipe 410 is in close contact with the first groove 110, when an external force occurs due to an earthquake or shock, there is a gap between the close contact protrusion 411 and the first groove 110. friction occurs.

In the above, the present invention has been shown and described with specific preferred embodiments, but the present invention is not limited to the above-described embodiments, and those skilled in the art within the scope of not departing from the spirit of the present invention Various changes and modifications will be possible by the person.

100: insulation plate 110: first groove
120: protrusion 121: locking jaw
130: virtual space 140: second home
150: 3rd groove 160: 4th groove
170: seating jaw 171: seating groove
180: fitting part 180a: hooking part
181: fitting groove 181a: locking groove
190: cutting groove 200: hot water heat sink
210: electric heat sink 300: upper plate
400: Heating pipe fixing member for dry composite heating system
410: fixed pipe 411: close protrusion
420: hooking part 430: contacting part
1000: dry complex heating system

Claims (3)

A number of them are installed adjacent to the bottom surface 1a of the building 1, and on one side, first grooves 110 in the form of a grid are formed at regular intervals to form a plurality of protrusions 120, and the protrusions 120 is divided into N x N virtual spaces 130, and second grooves 140 in a circular shape are formed based on the center of the virtual space 130, and the second grooves 140 are formed in the virtual space 130. The first groove 110 and the adjacent second groove 140 overlap each other in width, and a third groove 150 in a circular shape is formed in the center of the virtual space 130, and the virtual space An insulating board 100 in which a fourth groove 160 in a circular shape is formed between the second and third grooves 140 and 150 based on the center of 130; In the dry combined heating system 1000 including the hot water heat radiation pipe 200 or the electric heat radiation pipe 210 inserted into the first, second, third, and fourth grooves 110, 140, 150, and 160,
It is inserted into the first groove 110 formed between the protrusions 120 disposed at the corners of each virtual space 130, and the hot water heat radiation pipe 200 or the electric heat radiation pipe 210 is inserted into the first groove 110. In the heat radiation pipe fixing member 400 for a dry composite heating system that fixes,
The heat radiation tube fixing member 400 for the dry combined heating system is inserted into the first groove 110, and one side is open through an open inlet to which the hot water heat radiation pipe 200 or the electric heat radiation pipe 210 is inserted. (410); A hanging portion 420 formed vertically on both sides of the open inlet of the fixing pipe 410 and holding the hot water heat dissipating pipe 200 or the electric heat dissipating pipe 210 inserted into the fixing pipe 410; It includes a contact portion 430 formed horizontally on one side of the hooking portion 420 and in close contact with the upper surface of the protruding portion 120,
A locking jaw 121 is formed on the facing surfaces of the protrusions 120 disposed at the corners of each virtual space 130 to hold the fixing tube 410 inserted into the first groove 110,
The hooking part 420 is formed obliquely on both sides of the open inlet of the fixing pipe 410 so that the width of the open inlet of the fixing pipe 410 is narrowed,
A heat radiation pipe fixing member for a dry combined heating system that prevents the heat radiation pipe from leaving, characterized in that a plurality of contact protrusions 411 are formed on the outer surface of the fixed pipe 410 to be in close contact with the first groove 110. delete delete

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