KR20210128821A - System dry heating - Google Patents

Abstract

The present invention relates to a systematic dry heating device which comprises insulation and sound absorption panels with predetermined dimension arranged in a heating area to have pipe installation groove units for installing a heating pipe arranged on an upper surface portion, wherein the insulation and sound absorption panel includes: a plurality of sound absorption layers, at least one of which is disposed on a base unit or a top unit; and one or more sound insulation layer interposed between the sound absorption layers, wherein the sound absorption layers and the sound insulation layers are alternately disposed and a plurality of inner room units are arranged on the base surface of the sound absorption layer disposed on the base unit and the top unit to provide air layers. According to the present invention, compared to a conventional heating device for piping, the panels and the pipes can be readily installed and an assembling process is simple. Furthermore, an impact on a concrete bottom unit is alleviated to enhance blocking of noises and damping performance, thereby preventing interlayer noises.

Description

System dry heating

The present invention relates to a system dry heating system, and more particularly, to a system dry heating system used for piping of a hot water pipe.

In residential buildings, a heating pipe and finishing mortar for hot water circulation are constructed on the upper part of lightweight foundation concrete of a certain thickness disposed on a concrete layer, and a finishing material is installed on the upper surface after a drying period.

The floor surface of the ondol is a pipe structure during the construction process, and the hot water heated by the boiler is circulated into the inside of the heating tube to be heated. The heating pipe is fixed by installing a heating pipe fixture on the upper surface of the concrete foundation in order to maintain the bent state and the arranged spacing.

In recent years, insulation boards for the installation of heating pipes are mainly used. The insulation board makes it easier to construct an ondol floor and increases the heating efficiency.

The insulation board for heating pipe pipe is made of an insulating material that is spread to a predetermined thickness on the upper part of the concrete layer forming the floor surface of a building to maintain the warmth of the room, and support grooves or protrusions for installing the heating pipe are formed in the upper part. A heat transfer plate for diffusion of heat generated from the heating tube is installed on the upper surface of the insulation board, and a finishing material is installed on the upper surface.

The insulation board located under the existing heat transfer plate is contracted by a load intensively applied to the legs or a specific part of the furniture placed on the upper part, and the heat transfer plate positioned on the upper part is deformed due to the shrinkage, and the deformation is the ondol floor. There was a problem in that it was difficult to maintain a smooth state of the surface.

Moreover, since the heating device using the existing insulation panel has a complicated assembly structure for installing a pipe on the insulation panel to keep it flat, a highly skilled person is required for the installation, and if a separate cushioning material is not installed further, noise There was a problem in that the blocking and damping were not good.

An object of the present invention is to provide a system dry heating device that is easier to install than a conventional heating device for piping, a simple assembly operation, and has high noise blocking and damping performance by reducing the impact on the concrete floor. .

The system dry heating device according to the present invention has a predetermined standard and is arranged in a heating area, and is arranged in a heating area with a predetermined standard, and a heat-insulating sound-absorbing panel in which a pipe installation groove for installing a heating pipe is provided on the upper surface. Including, wherein the heat-insulating sound-absorbing panel includes a plurality of sound-absorbing layers disposed on the base and the uppermost part, and one or more sound-insulating layers positioned between the plurality of sound-absorbing layers, wherein the sound-absorbing layers and the sound-insulating layers are alternately arranged characterized.

It further comprises an assembly reinforcing means configured to be fixed by coupling the absorption layer and the sound insulation layer to each other, wherein the assembly reinforcement means is configured to be placed in an installation frame formed in the upper periphery of the heat-insulating sound-absorbing panel; A reinforcing frame including a standing frame that protrudes downward from the outside and surrounds the edge of the insulating sound-absorbing panel, and a fitting frame that protrudes downward from the inside of the anchi frame so as to be fitted and fixed in the fitting frame groove formed on the inside of the mounting frame and the lower end of the reinforcing frame may be spaced apart from the concrete floor by being positioned higher than the bottom of the sound-absorbing layer disposed on the base.

It further comprises an assembling reinforcing means configured to be fixed by coupling the absorption layer and the sound insulation layer to each other, wherein the assembly reinforcement means includes an auxiliary standing piece inserted into the auxiliary assembly hole formed to penetrate the absorption layer and the sound insulation layer, respectively, and the auxiliary assembly hole. It consists of an auxiliary assembly member including an auxiliary coupling member protruding laterally on the upper end of the auxiliary standing piece so as to be caught in the auxiliary assembly groove formed on the upper portion, and the lower end of the auxiliary assembly member is higher than the bottom portion of the sound-absorbing layer disposed at the base It can be characterized as being spaced apart from the concrete floor by positioning.

The lower end of the assembling reinforcing means may further include a lower cushioning member configured at the lower end of the assembling reinforcing means for buffering the impact on the floor concrete transmitted through the assembling reinforcing means.

A coupling protrusion configured to protrude from one side of the anchi frame, and a pipe coupling groove configured to the anchi frame so that the coupling protrusion is coupled to the other reinforcement frame may be characterized in that a plurality of heat-insulating sound-absorbing panels can be interconnected.

A vertical locking protrusion protruding downwardly from the end of the coupling protrusion, and further comprising a vertical locking groove formed in the heat insulation sound-absorbing panel so that the vertical locking protrusion penetrates the pipe coupling groove and is vertically coupled, a plurality of heat-insulating sound-absorbing panels interconnecting coupling It may be characterized in that the fixing property of the protrusion is improved.

It may further include a pipe defect groove formed in the reinforcing frame to correspond to the pipe installation groove so that the heating pipe installed in the pipe installation groove passes through.

It may be characterized in that it further includes a through hole formed through the standing frame, and when the reinforcing frame is combined with another reinforcing frame, the through hole forms a space portion to increase the heat insulation effect and sound insulation effect.

A heat storage means installed in the heat insulation sound-absorbing panel, a plate-shaped groove formed on the upper surface of the insulated sound-absorbing panel so that the heat storage means is placed, and a transmission groove that communicates with the pipe installation groove and the plate-shaped groove so that the heat of the heating pipe is transferred to the heat storage means more Including, it may be characterized in that heat is dissipated from the heat storage means even when the hot water of the heating pipe is blocked.

One or more coupling protrusions protrude on the inside of the pipe installation groove, and it may be characterized in that the heating pipe coupled to the pipe installation groove is prevented from being separated by being caught by the coupling projection.

The present invention described above is easier to install than the conventional heating device for piping, the installation of the panel and the pipe is simple, and the impact on the concrete floor is alleviated and the noise blocking and damping performance is high, so that the noise between the floors is prevented. It is possible to provide a system dry heating system that can do this.

1 is a perspective view in which insulating sound-absorbing panels are combined with a reinforcing frame in a system dry heating system according to an embodiment of the present invention.
Figure 2 is an isolated three-dimensional view showing that the assembly means is coupled to the insulating sound-absorbing panel.
Figure 3 is an isolated three-dimensional view showing that the metal conductor and the heat storage means are coupled to the insulating suction panel to which the assembly means is coupled.
Figure 4 is a partial cross-sectional view showing the layered structure of the insulating sound-absorbing panel installed means for assembly.
5 is an enlarged three-dimensional view and a cross-sectional view showing the coupling of the coupling protrusion and the vertical locking protrusion of the reinforcing frame.
6 is a perspective view of an insulating sound-absorbing panel according to another embodiment.
7 is an exemplary view showing a coupling protrusion.

Hereinafter, a floodlight for road installation with high practical realization and industrial applicability among various possible embodiments of the present invention will be described with reference to the embodiments of specific components shown in the accompanying drawings.

Looking at the configuration of the present invention with reference to the drawings, it has a predetermined standard and is arranged in a heating area, and includes a heat insulating sound-absorbing panel 100 in which a pipe installation groove 101 for installing a heating pipe is provided on the upper surface, and the The insulating sound-absorbing panel 100 includes a plurality of sound-absorbing layers 111 disposed on a base and an uppermost portion, and one or more sound-insulating layers 112 positioned between the plurality of sound-absorbing layers 111 , and the sound-absorbing layer 111 . ) and the sound insulation layer 112 are characterized in that they are alternately arranged.

The absorption layer 111 and the sound insulation layer 112 further include an assembly reinforcing means 120 configured to be fixed to each other, wherein the assembly reinforcing means 120 is at the upper periphery of the heat insulation sound-absorbing panel 100 . Anchi border 123 configured to be placed in the formed anchi border portion 116-1, and a standing border 122 that protrudes downward from the outside from the anchi border 123 and surrounds the edge of the insulating sound-absorbing panel 100. and a reinforcing frame 121 including a fitting frame 124 protruding downward from the inner side of the set frame 123 so as to be fitted and fixed in the fitting frame groove 116 formed on the inside of the set frame 116-1 and the lower end of the reinforcing frame 121 may be spaced apart from the concrete floor by being higher than the bottom of the sound-absorbing layer 111 disposed at the base.

The absorption layer 111 and the sound insulation layer 112 further include an assembling reinforcement means 120 configured to be fixed to each other, wherein the assembly reinforcement means 120 includes the absorption layer 111 and the sound insulation layer 112 . The auxiliary standing piece 131 inserted into the auxiliary assembly hole 118 formed so as to penetrate each of the auxiliary assembly holes 118 and the auxiliary assembly groove 119 formed on the upper portion of the auxiliary assembly hole 118 to be caught in the upper end of the auxiliary standing piece 131 laterally It is made of an auxiliary assembly member 130 including a protruding auxiliary coupling member 132, and the lower end of the auxiliary assembly member 130 is positioned higher than the bottom portion of the sound-absorbing layer 111 disposed at the base, so that the floor concrete It may be characterized as being spaced apart from

The lower end of the assembling reinforcing means 120 further includes a lower cushioning member 140 configured at the lower end of the assembling reinforcing means 120 for buffering the impact on the floor concrete transmitted through the assembling reinforcing means 120. can be characterized as

A coupling protrusion 127 configured to protrude from one side of the resting frame 123, and a pipe coupling groove 128 configured in the resting frame 123 so that the coupling protrusion 127 is coupled to the other reinforcing frame 121. It may be characterized in that a plurality of heat-insulated sound-absorbing panels 100 can be interconnected.

Vertical locking projection 127a formed to protrude downward from the end of the coupling protrusion 127, and the vertical stopping projection 127a penetrates the pipe coupling groove 128 and vertically formed on the heat insulation sound-absorbing panel 100 to be vertically coupled. By further including a locking groove 117, it may be characterized in that the fixing property of the coupling protrusion 127 for interconnecting the plurality of heat-insulating sound-absorbing panels 100 is increased.

It may further include a pipe defect groove 129 formed in the reinforcing frame 121 to correspond to the pipe installation groove 101 so that the heating pipe installed in the pipe installation groove 101 passes.

Further including a through hole 122a that is formed through the standing frame 122, the through hole 122a forms a space when the reinforcing frame 121 is coupled with the other reinforcing frame 122, thereby providing heat insulation and sound insulation effects. It may be characterized in that it is made to increase.

The heat storage means 115 installed in the heat insulation sound-absorbing panel 100, the plate-shaped groove 113 formed on the upper surface of the heat insulation sound-absorbing panel 100 so that the heat storage means 115 is placed, and the heat of the heating pipe heat storage means 115 ), further comprising a transmission groove 114 communicating the pipe installation groove 101 and the plate-shaped groove 113 so that the heat is dissipated from the heat storage means 115 even when the hot water of the heating pipe is blocked. can

One or more coupling protrusions 102 protrude from the inside of the pipe installation groove 101 to prevent the heating pipe coupled to the pipe installation groove 101 from being caught by the coupling projection 102 and separated. have.

The configuration of the system dry heating system described above in more detail along with the operation is as follows.

1 to 3, the system dry heating device according to an embodiment of the present invention is fixed by interconnecting the insulating sound-absorbing panel 100 and the insulating sound-absorbing panel 100 arranged in the heating area having a certain standard. It includes an assembly reinforcing means (120).

The heat insulation sound-absorbing panel 100 is arranged in a rectangular shape in the heating area to make a grid-like arrangement, and a pipe installation groove 101 for installing a heating pipe 10 through which hot water passes is provided on the upper surface in various shapes. can be

As shown in FIG. 4 , the heat insulating sound-absorbing panel 100 includes a plurality of sound-absorbing layers 111 having at least one disposed on the base and the uppermost portion, and one or more sound-insulating layers 112 positioned between the plurality of sound-absorbing layers 111 . ) is included.

When two or more sound insulation layers 112 are configured, the inner space 105 may be formed in the water absorption layer 111 formed under the sound insulation layer 112 to double the insulation function, sound insulation function, and cushion function. have.

The absorption layer 111 is mainly made of EPS material, and the EPS is expanded by the action of a foaming agent. also do It is white and light, and it is widely used because of its excellent water resistance, heat insulation, sound insulation, and buffering properties.

The sound insulation layer 112 is mainly made of EVA material, and the EVA is ethylene vinyl acetate (EVA), a material produced by copolymerizing an ethylene monomer and a vinyl acetate (VA) monomer. It is used to manufacture various products such as Hot Melt Adhesive (HMA), solar encapsulants, foam products such as shoe midsoles and buoys, and film products used for plastic houses and safety glass.

According to the present embodiment, three sound-absorbing layers 111 and two sound-insulating layers 112 are alternately arranged, and a plurality of interiors for providing an air layer on the bottom of the sound-absorbing layer 111 disposed on the base and uppermost part A space portion 105 is provided. The inner space 105 may also be provided in the sound insulation layer 112 in the middle portion, which is disposed to intersect with the other inner space 105 , and thus may not be expressed in the cross-sectional shape. The inner space 105 is to form an air layer, thereby performing heat insulation, shock damping, and noise canceling action.

The thickness of the insulating sound-absorbing panel 100 according to the present embodiment may be determined as follows in the vertical order.

1. Sound-absorbing layer (30mm): including a pipe seating groove and a lower groove in the upper part.

2. Sound insulation layer (5mm)

3. Sound-absorbing layer (30mm)

4. Sound insulation layer (5mm)

5. Sound-absorbing layer (30mm): Including the internal space part that is a buffer groove at the bottom.

The heat insulation sound-absorbing panel 100 may further include a heat storage means 115 installed to provide an additional heat retention function. Accordingly, a plate-shaped groove 113 for installing the heat storage means 115 may be provided on the upper surface of the heat insulating sound-absorbing panel 100 .

The heat storage means 115 is provided in a rectangular shape in this embodiment, and heat can be transferred to the heating pipe 10 through the transmission groove 114 connected to the plate-shaped groove 113 . A heat transfer member connecting the heating pipe 10 and the heat storage means 115 may be additionally installed in the transmission groove 114 .

Although the absorption layer 111 and the sound insulation layer 112 may be manufactured to be adhered to each other, it is desirable to further include an assembling reinforcing means 120 configured to be assembled and fixed by being coupled to each other for ease of maintenance and improvement of productivity. do.

The assembly reinforcing means 120 may selectively configure the reinforcing frame 121 and the auxiliary assembly member 130 as shown in FIG. 2 in this embodiment, and in particular, the reinforcing frame 121 will be described later. Since it can be further configured to be combined with other assembly and reinforcement means 120, it will be preferable to configure the heat insulation suction panel 100 as essential because it is useful for arrangement and installation.

In the case of the reinforcing frame 121 , the inner frame 123 is configured to be placed on the inner frame 116-1 formed in the upper periphery of the insulating sound-absorbing panel 100 .

Since the insulation sound-absorbing panel 100 is generally manufactured in a rectangular shape for ease of installation, the anchi border 123 will also be a hollow rectangular border shape to correspond to the shape of the insulation sound-absorbing panel 100, and the anchi border part The height of the upper surface of the anchi border 123 placed in (116-1) is the same as the height of the top surface of the heat insulating sound-absorbing panel 100, and the depth of the anchored border part 116-1 and the height of the anchor border 123 are the same. it is preferable

A standing border 122 is formed to surround the edge of the insulating sound-absorbing panel 100 that protrudes downward from the inner border 123 to the outside, and the standing border 122 is sandwiched between the absorption layer 111 and the sound insulation layer 112 . By combining, it is possible to increase the fixability of the heat insulating sound-absorbing panel 100 and reinforce the supporting force.

A fitting frame groove 116 that is deeper than the inside edge portion 116-1 is further formed on the inner side of the set frame 116-1, and the inner side of the set frame 123 so as to be coupled to the fitting frame groove 116. It is possible to further form a fitting border 124 that protrudes downward from the.

As shown in FIG. 7 , a coupling protrusion 127 is formed to protrude laterally from one side of the anchi frame 123 , and a protrusion coupling groove 128 corresponding to the coupling protrusion 127 is formed of the anchi frame 123 . formed on the other side.

Therefore, as shown in FIG. 5, when a plurality of heat-insulating sound-absorbing panels 100 are arranged and installed, two or more reinforcing frames 121 coupled to the rim of each heat-insulating sound-absorbing panel 100 are attached to each other, so the reinforcing frame 121. The coupling protrusion 127 protruding from one side of the is to be inserted into the protrusion coupling groove 128 formed on one side of the reinforcing frame 121 on multiple sides.

As the coupling protrusion 127 is inserted into the protrusion coupling groove 128 , the vibration is reduced when the heat insulating sound-absorbing panel 100 is installed, and it is easy to install in an accurate position.

Considering the shape of the room in which the insulating sound-absorbing panel 100 is installed, in order to facilitate installation from one side of the room, the coupling protrusion 127 protrudes only on two adjacent sides of the four sides of the reinforcing frame 121, and the remaining It will be preferable that the projection coupling groove 128 is installed on the two sides.

The end of the coupling protrusion 127 is further configured with a vertical stopping protrusion 127a that is formed to protrude further downward, and the vertical stopping protrusion 127a penetrates through the protrusion coupling groove 128 and is vertically coupled to the insulating suction panel ( 100) is fitted to the vertical locking groove 117 formed on the upper surface.

Therefore, the coupling protrusion 127 can be firmly coupled without falling into the protrusion coupling groove 128 .

Several through-holes 122a may be further formed in the standing border 122 .

The through-hole 122a is such that when the reinforcing frame 121 is coupled to the other reinforcing frame 122, a pair of through-holes 122a facing each other form a space to increase the heat insulation effect and sound insulation effect.

The heating pipe is installed in the pipe installation groove 101 formed in the heat insulation sound-absorbing panel 100, and at this time, the coupling protrusion ( 102) to protrude thinly, so that it can be coupled to be caught.

A pipe coupling groove 129 may be further formed in the reinforcing frame 121 .

As the heating pipe coupled to the pipe installation groove 101 protrudes long to the side, there is no choice but to physically interfere with the reinforcing frame 121, so that the reinforcing frame 121 and the heating pipe do not interfere with each other. A pipe coupling groove 129 may be further configured in the frame 121 .

As the assembly reinforcing means 120 , the auxiliary assembly member 130 is configured as follows.

Each of the absorption layer 111 and the sound insulation layer 112 is formed with an auxiliary assembly hole 118 formed to vertically penetrate each, and an auxiliary standing piece 131 coupled to the auxiliary assembly hole 118 is formed.

Since the auxiliary rising piece 131 is formed in a thin plate shape in the embodiment, the shape of the auxiliary assembling hole 118 will also preferably have a thin and long shape to correspond to the auxiliary rising piece 131 .

In order to prevent the auxiliary rising piece 131 from being separated from the opposite side, the auxiliary coupling member 132 is protruded from the upper end of the auxiliary rising piece 131, and the auxiliary assembly member 130 has an approximately T-shape.

An auxiliary assembly groove 119 communicating with the auxiliary assembly hole 118 of the suction layer 111 of the uppermost layer is further configured to correspond to the auxiliary coupling member 132, and the auxiliary coupling member 132 is provided in the auxiliary assembly groove 119. ) to be seated, and the depth of the auxiliary assembly groove 119 should be formed to be greater than or equal to the thickness of the auxiliary coupling member 132 , so that there will be no elements unnecessarily protruding from the upper surface of the heat insulating suction panel 100 .

The reinforcing frame 121 may be easily made of ABS, and if necessary, may be made of a material that is lightweight and provides sufficient toughness, such as aluminum, thin iron, or carbon composite material.

According to an embodiment (A) of Figure 4, the reinforcement frame 121 or the auxiliary assembly member 130, which is the assembly reinforcement means 120, is located higher than the bottom portion of the sound-absorbing layer 111 disposed at the base, so that the floor concrete It is spaced apart to provide a date space 124 in the.

Since the assembly reinforcing means 120 is a hard material unlike the heat insulating sound-absorbing panel 100 , it can transmit a load to the concrete floor on the heat-insulating sound-absorbing panel 100 . Such a load may act as an impact on the floor concrete and cause problems such as inter-floor noise, but the height between the lower end of the assembly reinforcing means 120 and the ground is set a predetermined distance so that the lower end of the assembly reinforcing means 120 does not touch the floor concrete. You can solve this by forming it to float.

According to another embodiment (B) of FIG. 4 , the lower end of the assembly reinforcing means 120 may be provided with a lower buffering member 140 for buffering the impact on the concrete floor transmitted through the assembling reinforcing means 120 . have.

The lower cushioning member 140 is coupled along the bottom bottom of the assembling reinforcing means 120 to buffer the overall load acting on the assembling reinforcing means 120 , and the floor concrete by the load applied by the assembling reinforcing means 120 . It is possible to prevent the shock transmitted to the

The coupling method may be bonding, but as shown in the drawings, a buffer groove is formed at the lower end in the longitudinal direction of the assembly reinforcing means 120 , and a coupling protrusion corresponding to the buffer groove is formed on the lower buffer member 140 . It can be formed and fitted.

By disposing the lower cushioning member 140 of the same thickness along the lower end of the assembly reinforcing means 120 rather than the insulating sound-absorbing panel 100, it is possible to solve the impact problem applied to the concrete floor.

A plate-shaped groove 113 may be formed on the upper portion of the heat insulation suction panel 100 so that the heat storage means 115 is coupled to the plate-shaped groove 113 .

Since the plate-shaped groove portion 113 and the pipe installation groove portion 101 are formed to communicate with each other by the transmission groove portion 114 , heat energy emitted from the hot water of the heating pipe installed in the pipe installation groove portion 101 is transmitted through the transmission groove portion 114 . It is transmitted to the plate-shaped groove portion 113 to heat the heat storage means (115).

The heat storage means 115 generates heat and heat at the same time while the hot water in the heating pipe flows, and when the hot water in the heating pipe is cut off, the heat from the heat storage means 115 continues for a certain period of time to provide warmth to the room.

In addition, as shown in FIG. 3 , a metal conductor 150 may be further configured on the upper surface of the heat insulating sound-absorbing panel 100 .

When the metal conductor 150 is further included, the metal conductor 150 is formed with a groove to be inserted into the pipe installation groove 101 and the plate-shaped groove 113 through metal processing, so that the metal conductor 150 is an insulating sound-absorbing panel. It is to be interposed between the 100 and the heating pipe, and it can be interposed between the heat insulating sound-absorbing panel 100 and the heat storage means 115 .

As described above, the metal conductor 150 evenly conducts heat energy received from the hot water of the heating pipe to the metal plate, thereby heating the entire floor of the room.

Even if the heating pipe is submerged in hot water, the heat energy emitted from the heat storage means 115 that has been heated is conducted by the metal conductor 150 and is induced to be evenly dispersed and dissipated without being concentrated in one place as the warmth of the floor.

6 to 7 , the pipe installation groove 101 of the heat insulating sound-absorbing panel 100 may provide various shapes corresponding to the refraction or straight lines and branches of the heating pipe.

Although the embodiments of the present invention have been described as described above, those of ordinary skill in the art based thereon can add or change components within the scope that does not depart from the essential technical spirit of the present invention described in the claims. , it will be possible to variously modify and change the present invention by deletion or addition, which is also included within the scope of the present invention.

100: insulation sound-absorbing panel 101: pipe installation groove 102: coupling protrusion 105: inner space
111: sound absorption layer 112: sound insulation layer
113: plate-shaped groove 114: transmission groove 115: heat storage means
116: Fitting border groove 116a: Anchoring border part
117: vertical locking groove 118: auxiliary assembly hole 119: auxiliary assembly groove
120: assembly reinforcement means
121: reinforcing frame 122: standing border 122a: through hole 123: anchored border 124: fitting border
127: coupling projection 127a: vertical locking projection 128: projection coupling groove 129: pipe coupling groove
130: auxiliary assembly member 131: auxiliary standing piece 132: auxiliary coupling member
140: lower buffer member
150: metal conductor

Claims (8)

It has a certain standard and is arranged in the heating area, and includes a heat insulating sound-absorbing panel 100 in which a pipe installation groove 101 for installing a heating pipe is provided on the upper surface,
The heat insulation sound-absorbing panel 100,
A plurality of sound-absorbing layers 111 disposed on the base and the top; and
It includes one or more sound insulating layers 112 positioned between the plurality of sound absorbing layers 111,
The sound-absorbing layer (111) and the sound-insulating layer (112) is a system dry heating system, characterized in that arranged alternately.
According to claim 1,
The absorption layer 111 and the sound insulation layer 112 further include an assembly reinforcement means 120 configured to be reinforced by being coupled to each other,
The assembly reinforcing means 120 is,
Anchi border 123 configured to be placed on the inner edge portion 116-1 formed in the upper periphery of the insulating sound-absorbing panel 100;
A standing border 122 that protrudes downward from the outside from the inner border 123 and is configured to surround the edge of the heat insulation sound-absorbing panel 100;
A fitting frame 124 that protrudes downward from the inside of the inside frame 123 so as to be fitted and fixed in the fitting frame groove 116 formed on the inside of the inside edge portion 116-1;
Consists of a reinforcing frame 121 comprising a,
The lower end of the reinforcing frame (121) is positioned higher than the bottom of the sound-absorbing layer (111) disposed at the base, so that it is spaced apart from the concrete floor.
According to claim 1,
The absorption layer 111 and the sound insulation layer 112 further include an assembly reinforcing means 120 configured to be fixed to each other,
The assembly reinforcing means 120 is,
Auxiliary erection pieces 131 inserted into auxiliary assembly holes 118 formed to penetrate through the absorption layer 111 and the sound insulation layer 112, respectively;
Auxiliary coupling member 132 protruding laterally on the upper end of the auxiliary erection piece 131 so as to be caught in the auxiliary assembly groove 119 formed in the upper portion of the auxiliary assembly hole 118;
A system dry heating system, characterized in that it consists of an auxiliary assembly member (130) comprising a reinforced support for the insulating sound-absorbing panel (100).
4. The method of claim 2 or 3,
The lower end of the assembling reinforcing means 120 further includes a lower cushioning member 140 configured at the lower end of the assembling reinforcing means 120 for buffering the impact on the floor concrete transmitted through the assembling reinforcing means 120. System dry heating system, characterized in that.
3. The method of claim 2,
a coupling protrusion 127 configured to protrude from one side of the antler border 123;
The coupling protrusion 127 is coupled to the other reinforcing frame 121, the protrusion coupling groove 128 configured in the rim 123;
A system dry heating system, characterized in that it is a coupling means that can interconnect a plurality of heat insulation sound-absorbing panels (100) further comprising a.
6. The method of claim 5,
a vertical locking protrusion 127a protruding downwardly from the end of the coupling protrusion 127;
Vertical locking groove 117 formed in the heat insulation sound-absorbing panel 100 so that the vertical locking protrusion 127a penetrates through the protrusion coupling groove 128 and is vertically coupled;
The system dry heating system, characterized in that it further comprises a plurality of heat-insulated sound-absorbing panels (100) to increase the fixability of the coupling protrusion (127) interconnecting each other.
3. The method of claim 2,
a through hole (122a) which is formed through the standing edge (122);
Furthermore, the system dry heating device, characterized in that, when the reinforcing frame 121 is combined with the other reinforcing frame 122, the through-hole (122a) forms a space to increase the heat insulation effect and the sound insulation effect.
According to claim 1,
Heat storage means 115 installed on the insulating sound-absorbing panel 100;
A plate-shaped groove 113 formed on the upper surface of the heat insulating sound-absorbing panel 100 so that the heat storage means 115 is placed;
a transmission groove 114 communicating the pipe installation groove 101 and the plate-shaped groove 113 so that the heat of the heating pipe is transferred to the heat storage means 115 ;
Further comprising a system dry heating system, characterized in that heat is emitted from the heat storage means (115) even when the hot water of the heating pipe is cut off.

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