KR102288012B1 - Hot Water Floor for Heating - Google Patents

Abstract

The present invention relates to a hot water floor for heating, and more particularly, by increasing the flow rate of hot water circulating in a flow path, improving the energy efficiency of the hot water floor for heating, collecting and detecting leakage of the hot water floor, and supporting a tapered wedge It relates to a hot water floor for heating that does not crack even when used for a long time by firmly coupling a cap member and a floor member formed integrally with each other.

Description

Hot Water Floor for Heating}

The present invention relates to a hot water floor for heating, and more particularly, by increasing the flow rate of hot water circulating in a flow path, improving the energy efficiency of the hot water floor for heating, collecting and detecting leakage of the hot water floor, and supporting a tapered wedge It is a hot water floor for heating that does not crack even when used for a long time by firmly bonding the cap member and the floor member formed integrally.

In general, for heating the floor of a building, a method of arranging hot water pipes and filling them with concrete mortar, and a method of assembling a hot water flow path inside the floor are used.

In the case of the method using concrete mortar, there are many difficulties in demolition and repair work, and there is a problem that it takes a lot of time to cure the concrete during installation.

Recently, a method of assembling a hot water floor in which a hot water flow path is formed has been widely used.

For example, Korean Patent Publication Nos. 10-1392634, 10-1438490, 10-1286606, 10-1164871, 10-1039317, 10-0712426, 10-0664463, Patent Publication Nos. 10-2017-0041085, 10-2014-0090490, 10-2013-0133953, 10-2011-0119283, etc. disclose various technologies for heated flooring.

"형상으로 설치되어 마루부재의 바닥면이 높아지고, 천정의 높이가 낮아지게 되므로, 기존의 방바닥을 철거해야하는 문제가 있었다. 이에 따라서, 소음과 공사의 규모가 커지고, 작업자가 부담해야하는 비용이 증가하고, 시공 기간이 오래 걸린다는 문제점이 있었다.However, in the case of a conventional hot water floor, as shown in FIG. 1A , in the cap member 200, a portion to which the connector 210 is coupled and a portion to which the floor member 100 is coupled are at right angles to increase the installation height of the heated floor or FIG. 1B . The connecting hose inserted into the cap member is

"As it is installed in a shape, the floor surface of the floor member becomes higher and the height of the ceiling becomes lower, so there was a problem that the existing floor had to be removed. Accordingly, the noise and the scale of the construction increase, and the cost to be borne by the worker increases. , there was a problem that the construction period took a long time.

In addition, as shown in FIGS. 1A and 1B , in the conventional hot water floor, a plurality of hot water flow paths are formed inside the floor member, and the hot water passes through the plurality of flow paths to improve thermal efficiency. There was a problem that the use of a larger capacity boiler and pump is required to circulate at a high speed.

In addition, as shown in FIG. 1C, in the "air-conditioning and cooling circulator using a panel" of Korean Patent Application Laid-Open No. 10-2015-0142400, a plurality of holes are formed inside the floor member to suppress heat transfer to the lower part of the floor member and to facilitate heat transfer to the upper surface of the floor member. It is formed to supply hot water to the upper hole, and the lower hole is blocked with packing to form an air layer, thereby reducing heat loss.

In addition, flooring members or hoses that use hot water have a problem in that, if leaks are not detected at an early stage due to manufacturing defects or aging, it can cause great damage to the lower floors, etc. .

Prior Document 1: Korean Patent Publication No. 10-0712826 (207.05.07.) Prior Document 2: Korean Patent Publication No. 10-1925952 (2018.12.05.) Prior Document 3: Korean Patent Application Laid-Open No. 10-2015-0142400 (2015.12.22.) Prior Document 4: Korea Patent Publication No. 10-2006-0090956 (2006.08.17) Prior Document 5: Japanese Laid-Open Patent Publication No. 10-2004-138349 (2004.05.03)

An object of the present invention is to provide a hot water floor for heating for improving the flow of a circulation circuit in which hot water is circulated by sealing some of the plurality of hot water channels and using only the other hot water channels.

In addition, the present invention prevents the height of the ceiling from being lowered and reduces the construction cost and construction period by forming a low-water floor by aligning the floor member, the cap member, and the hose to the same height so that the floor can be constructed without dismantling the floor. The purpose is to provide a hot water floor for heating that can reduce the

Another aspect of the present invention is to provide a hot water floor for heating with excellent thermal efficiency by using a material that is good for heat conduction from hot water for the upper part of the flooring member and coating the floor with a material with low thermal conductivity and a thermal barrier agent for the bottom of the hot water flooring member. There is a purpose.

In addition, in the present invention, a tapered wedge support part is integrally formed on the cap member, inserted into the hot water flow path of the floor member where hot water does not flow when combined with the floor member, and heat-sealed. Another object is to provide a hot water floor for heating that does not cause this.

According to an embodiment of the present invention, a plurality of flooring members 100 are arranged adjacent to each other, and a plurality of hot water flow paths 140 are formed in parallel in the longitudinal direction inside the flooring member 100, and the flooring member ( In the hot water floor for heating in which a plurality of hot water flow paths 140 are communicated with each other by the cap member 200 coupled to both ends of the 100) and the hot water supplied from the flow path connection pipe 40 is circulated, the floor member ( 100), the cap member 200, and the flow path connection pipe 40 are arranged in a straight line at the same height on a plane, some of the plurality of hot water flow paths 140 do not supply hot water, and the other hot water flow paths do not supply hot water. It is characterized in that only the flow path supplies hot water.

The floor member 100 is characterized in that one to five pieces of one floor module M are formed, and each floor module M is integrally molded.

The hot water flow path 140 of the floor member 100 is formed in five, but the 1st, 3rd, and 4th hot water flow paths do not supply hot water, and only the 2nd and 5th hot water flow paths supply hot water. do.

The cap member 200 is characterized in that the tapered wedge support part 240 inserted into the third hot water flow path 143 when combined with the floor member 100 is integrally formed.

The cap member 200 is characterized in that one is formed for each floor module (M).

The upper part 110 of the floor member 100 is made of a heat transfer member made of carbon powder or carbon fiber having high thermal conductivity, and the lower part 120 is made of a heat insulating member that blocks heat transfer.

The upper surface of the upper part 110 is characterized in that any one of a cypress wood pattern film, a copper thin plate, and an aluminum thin plate is attached.

The bottom surface 122 of the floor member is coated with a heat-blocking material.

Joint grooves 150 are formed at both corners of the floor member 100 or each module M, and a “ㅛ”-shaped joint hole is formed between the joint grooves 150 of adjacent floor members 100. (170) is characterized in that it is inserted and installed.

Each floor module (M) connects a floor member having a large number of hot water flow paths to the hose side 300 for supplying hot water to the boiler so that the flow rate is slow, and the receiving hose side is connected to a floor member having a small hot water flow path to increase the flow rate. It is characterized in that it is circulated so that the temperature can be evenly distributed.

A pair of bare wires 190 are semi-buried on both sides of the bottom surface of the floor member 100 or each floor module M in parallel as shown in FIG. 7 , and power is supplied to both sides of the plurality of bare wires 190 . It is characterized in that the water leak alarm circuit 400 is connected to detect water leakage, so that when water is detected in the bare wire 190, an alarm is issued.

According to the heated floor for heating according to the embodiment of the present invention, the floor member, the cap member, and the hose are aligned at the same height to form a low height of the heated floor so that the floor can be constructed without removing the floor, which is lower than the conventional heated floor. It has the effect of providing a heated floor for heating that can prevent the height of the floor from increasing and reduce the construction cost and construction period.

In addition, according to the hot water floor for heating according to the embodiment of the present invention, it is possible to prevent a decrease in the circulation speed of hot water by using only some of the hot water flow paths among the plurality of hot water flow paths, and by improving the flow rate of hot water, the pump and The boiler capacity is reduced, and there is an effect that it is possible to provide a hot water floor for heating which can increase the energy use efficiency of hot water for heating.

In addition, according to the hot water floor for heating according to the embodiment of the present invention, 1 to 5 floor members are molded*?* into one floor module (M), and the cap member is 1 for each floor module (M). It has the effect of providing a hot water floor that can be easily and conveniently installed by combining each module according to the area to be installed and is easy to install by forming a dog.

In addition, according to the hot water floor for heating according to the embodiment of the present invention, the cap member integrally forms a tapered wedge support part so that when combined with the floor member, it is firmly inserted into the hot water flow path to which hot water is not supplied, and the cap member and the floor member. It has the effect of providing a hot water floor that does not crack at the bonding site even after long-term use by thermal fusion bonding.

In addition, according to the hot water floor for heating according to the embodiment of the present invention, heat from the hot water is prevented from being emitted toward the floor and lower cement of the building by manufacturing it with different materials so that the upper and lower heat conduction efficiencies of the floor member are opposite to each other. , there is an effect of providing a hot water floor for heating that can further increase the conduction of heat used for heating.

In addition, according to the hot water floor for heating according to an embodiment of the present invention, any one of a cypress wood pattern film, a copper foil plate, and an aluminum foil plate is integrally attached to the upper surface to improve health or to transfer heat well. .

Further, according to the hot water floor for heating according to the embodiment of the present invention, a pair of bare wires are buried in parallel on both sides of the floor member or the floor surface of each floor module M in parallel to detect water leakage by the bare wires. , by allowing the location of the leak to be determined using the resistance value calculated by the bare wire, it is possible to prevent the leak from spreading significantly.

1 is a perspective view showing a conventional hot water floor for heating.
2 is an exploded perspective view showing a floor member, a cap member, and the like in the hot water floor for heating according to an embodiment of the present invention.
3 is an exploded perspective view showing a floor member, a cap member, etc. made of modules in the hot water floor for heating according to an embodiment of the present invention.
4A is a side view for explaining that the material of the upper part and the lower part of the flooring member are different in the heated heated flooring for heating according to an embodiment of the present invention.
4B is a side view illustrating a flooring member coated with a conductive material on the upper surface of the uppermost layer and a lower surface of the lowermost layer with a thermal barrier in the heated heated flooring for heating according to an embodiment of the present invention.
4C is a perspective view showing a floor member having a cypress pattern attached to the upper surface of the uppermost layer in the heated heated floor for heating according to an embodiment of the present invention.
5 is a plan view for explaining the classification according to the configuration of the module of the hot water floor for heating according to an embodiment of the present invention.
6 is a plan view showing the arrangement of hoses and combining the modules of the hot water floor for heating according to the size of the room according to an embodiment of the present invention.
7 is a plan view showing a bare wire for detecting a leak of a hot water floor for heating according to an embodiment of the present invention.
8A is a circuit diagram illustrating a configuration example of a detection circuit and an alarm circuit to which a plurality of bare wires are applied in the hot water floor for heating according to an embodiment of the present invention.

Next, a preferred embodiment of the hot water floor for heating according to the present invention will be described in detail with reference to the drawings. The present invention can be implemented in various various forms, and is not limited to the embodiments described below. Hereinafter, in order to clearly explain the present invention, detailed descriptions of parts not closely related to the present invention are omitted, and the same reference signs are attached to the same or similar components throughout the description of the invention, and repeated descriptions are omitted. .

As shown in FIGS. 2A and 2B , in the hot water floor for heating of the present invention, a plurality of floor members 100 are arranged adjacent to each other, and a plurality of hot water flow paths 140 in the longitudinal direction are disposed inside the floor member 100. formed side by side By the cap member 200 coupled to both ends of the floor member 100 , a plurality of hot water flow paths 140 communicate with each other, and the hot water supplied from the flow path connection pipe 40 circulates.

The floor member 100, the cap member 200, and the flow path connection pipe 40 are arranged in a straight line at the same height on a plane, and some of the plurality of hot water flow paths 140 do not supply hot water. , it has a structure in which hot water is supplied only with the other hot water oil. According to the present invention, since the hot water supplied from the flow path connection pipe 40 is horizontally supplied to the cap member 200 and the floor member 100, the total height of the hot water floor is lowered compared to the prior art, so that the user can install the hot water floor, It has the effect of increasing convenience by installing it on the floor without having to remove the floor of the room. That is, in the prior art, as shown in FIG. 1, the hose was formed in a U-shape at the bottom, and the installation height of the hot water floor was as high as 7 cm. and the cap member 200 and the flow path connector 40 are arranged in a straight line at the same height on the plane and have a height of 2 cm or less, so it has the advantage of being able to construct directly on top of the floor without tearing it off. It has the advantage of reducing noise and greatly reducing manpower and time.

In addition, a pair of connector 210 is provided on both sides of the cap member 200 , respectively, and the flow path connector 40 is installed by being coupled to the end of each connector 210 . In addition, the present invention forms a thread on the outer circumferential surface of the connector 210 and firmly fixes the channel connector 40 coupled to the connector 210 using a hose clamp 220 , so that the channel connector 40 ) to prevent separation and drop-out. Since the flow path connection pipe 40 is made of silicone or soft synthetic resin material, it has excellent flexibility, so that the connection operation of the flow path connection pipe 40 is made easily. In this case, the occurrence of cracks can be minimized.

As shown in FIGS. 2 and 3 , the hot water floor for heating of the present invention has a structure in which hot water is not supplied to some of the hot water flow paths 140 and only the other hot water flow is supplied. 2 to 3, hot water is supplied to the second hot water channel 142 and the fifth hot water channel 145 or the first hot water channel 141 and the fourth hot water channel 144, and the cap The member 200 is provided with a plurality of protrusions 230 to match the position of the hot water flow path for supplying hot water to the floor member 100 . Usually, the width of the hot water floor is 10 to 20 cm. When five hot water passages 140 are formed on one floor member 100, the hot water passages are supplied to the second and fifth (or the first and fourth) as shown in FIG. 3B . Considering the positions of the coupling grooves 150 formed on both sides of the flooring member 100 when combined with the adjacent flooring member, the hot water supply interval is most evenly arranged, so that the room can be uniformly warmed. In addition, it has a structure that can implement a stable coupling structure with the hot water flow path in the center when considering the wedge support 240 and coupling to be described below. Of course, by a person skilled in the art, it is possible to use an odd or even number of hot water flow paths, use only the middle number 3, or use 1 and 5 on the side with various modifications such as use. As described above, the structure in which hot water is not supplied to some of the plurality of hot water flow paths 140 and only hot water is supplied to the other hot water flow channels by preventing a decrease in the circulation speed of hot water and improving the flow rate of hot water, There is an effect that the capacity of the pump and the boiler is reduced, and it is possible to provide a hot water floor for heating which can increase the energy use efficiency of hot water for heating.

The present invention is limited to supplying hot water to the second hot water channel 142 and the fifth hot water channel 145 or the first hot water channel 141 and the fourth hot water channel 144 among the plurality of hot water channel 140 . Instead, as shown in FIG. 4C , only one of several, only odd or even numbers, or both odd and even numbers may be used.

On the other hand, the cap member 200 provided with the protrusion 230 is integrally coupled to both ends of the floor member 100 by thermal fusion, thereby reducing the risk of separation of the cap member 200 and the flow path connecting pipe ( 40), there is an effect that the hot water supplied from the floor member 100 can be stably circulated.

In the present invention, in FIG. 2 , the first hot water channel 141 and the fourth hot water channel 144 of the floor member 100 are not used, and the second hot water channel 142 and the fifth hot water channel are not used. The hot water is circulated in the flow path 145 and used, and the wedge support 240 is inserted into the third hot water flow path 144 formed in the center to be coupled thereto. The unused hot water furnaces 141 and 144 can be used without sealing or sealing the floor member 100 with silicone or the like during the construction process.

The floor member 100 of the present invention can be manufactured by integrally molding one to five pieces of one floor module (M). It can be molded into a dog. Conventional hot water flooring, as shown in Fig. 2, was manufactured by assembling and constructing one by one on site, so construction was difficult and time-consuming, and exclusive equipment such as a heat fusion machine was required. One module can be molded in the factory. In addition, as shown in FIG. 3 , the construction time can be greatly reduced because it is sufficient to construct only one floor module (M) in which three units are integrally constructed, as in the conventional assembly one by one. In addition, it has the advantage that it can be conveniently constructed by combining 5 types according to the installation area. Modularization of hot water flooring can be manufactured by integrating 6 or more, but it was found to be most efficient to use 1 to 5 units as one module in consideration of the size, transport, and assembly of the injection molding machine. In addition, as shown in FIG. 5 , one cap member 200 used in a floor module M in which one to five floor members is formed as one is formed for each floor module M according to the size. The structure as described above is convenient for construction because it is cut to fit the length of the floor at the factory, and the cap member 200 is fusion-bonded and then sent to the site. You have the advantage of being able to do it.

The cap member 200 of the present invention has a structure in which the tapered wedge support part 240 inserted into the third hot water flow path 143 is integrally formed when combined with the floor member 100 . The cap member 200 and the floor member 100 of the present invention are joined by thermal fusion, but when the wedge support part 240 is inserted into the third hot water flow path 143 where hot water does not flow, they come into contact with each other, and heat fusion is performed here. You can do it easily. In addition, the wedge support 240 having a tapered shape is easily inserted into the hot water flow path 143 with a thin tip as shown in FIG. 2C or 3C, and is firmly coupled in the form of an interference fit as it enters. In particular, arrow protrusions 240 in the shape of arrowheads are formed in the upper and lower portions in contact with the inner wall of the hot water flow passage 143 so as not to fall out when combined. Such a structure eliminates disadvantages such as an increase in parts such as packing and screws, an increase in assembly time, and water leakage at the joint, which occur when the cap member 200 and the floor member 100 are conventionally coupled with screws, and is combined only by thermal fusion. It is also a very effective method to prevent leakage due to cracks occurring in the joint due to external impact or pressing.

In the present invention, as shown in FIGS. 4A and 4B , the upper part 110 of the floor member 100 is made of a heat transfer member made of carbon powder or carbon fiber having high thermal conductivity, and the lower part 120 blocks heat transfer. It is made of an insulating member. The upper part 110 and the lower part 120 of the flooring member 100, which are materials with different heat conduction efficiency, are integrally produced by a molding machine, and the lower surface 122 of the flooring member 100 is a coating material that improves thermal insulation efficiency. coated with By making the upper part 110 of the flooring member 100 made of a heat transfer member made of carbon powder or carbon fiber, thermal conductivity can be greatly improved and a hot water floor for heating with high thermal efficiency can be provided. Depending on the method, as shown in FIG. 4B , the upper surface of the upper surface 110 of the flooring member 100 is coated with carbon powder, or a material emitting far-infrared rays such as jade, elvan stone, germanium stone, or charcoal is powdered. It can be manufactured and coated on the upper surface of the upper part 110 together with carbon powder. By coating the material emitting far-infrared rays, it is possible to provide a human-friendly hot water floor for heating that has effects such as active heat conduction, regeneration of human tissue, improvement of blood circulation, and promotion of excretion of harmful substances in the body. Meanwhile, the lower portion 120 of the floor member 100 is made of a heat insulating member. The heat insulating member includes materials such as PCTG, PCT, PC, PA, PP, PES, urethane resin, tritan synthetic resin, TBT and epoxy resin, which are strong and safe plastic materials with heat resistance or heat insulation properties. In addition, since it can be manufactured by weaving or laminating glass fibers having excellent fire resistance and heat resistance, the present invention is not limited thereto. In addition, the bottom surface 122 of the flooring member is coated with a coating material that improves thermal insulation efficiency, thereby preventing the heat of the flooring member 100 from being emitted toward the floor or cement of the building, thereby further increasing the thermal efficiency for heating. It has the effect of increasing it. Depending on the method, the coating material may be coated using a lacquer, paint, and adhesive containing a heat insulating composition.

Any one of a cypress wood pattern film, a copper thin plate, and an aluminum thin plate may be further attached to the upper surface of the upper part 110 of the flooring member 100 of the present invention, and the copper thin plate and the aluminum thin plate are coated with silver nano. It can enhance antibacterial activity. The above configuration may be manufactured in various ways in consideration of the constitution and health of the user.

2B, 4A, and 4B, joint grooves 150 are formed at both corners of the flooring member 100, and between the joint grooves 150 of adjacent flooring members 100 are formed. It is characterized in that the "ㅛ"-shaped joint 170 is inserted and installed. When the "ㅛ"-shaped joint 170 is inserted into the joint groove 150, both sides of the plurality of floor members 100 are maintained horizontally while being firmly connected to each other and fixed.

In the present invention, it is characterized in that the floor modules M are arranged in combination in an even number. As shown in FIG. 6A , when the number of floor modules M is combined with four according to the width of the room, there is an advantage in that the hose 300 for supplying and recovering hot water can be arranged on one side wall of the horizontal side. However, when the floor modules M are arranged in an odd number, the outlet hose 300 from which the hot water is recovered and enters the boiler is extended by the length of one side of the vertical wall as shown in FIG. 6B . Accordingly, in the present invention, by arranging the floor modules in an even number of tanks, there is an advantage in that the outlet hose can be disposed on one wall together with the incoming inlet hose.

Also, in the present invention, as shown in FIG. 6A , by arranging the floor modules M with more hot water channels at the inlet side where hot water is introduced and the floor modules M with fewer hot water paths toward the outlet, the flow rate becomes slower at the inlet side as shown in FIG. The exit side can have the effect of dissipating heat evenly throughout the floor by allowing it to circulate quickly.

A pair of bare wires 190 are semi-buried in parallel on both sides of the bottom surface of the floor member 100 or each floor module M of the present invention as shown in FIG. 7A . The bare wire 190 is added or subtracted according to the width of the floor member 100, and is manufactured as three wires as shown in FIG. 7B, and as shown in FIG. 8A, a circuit in which the middle bare wire is commonly used as a - pole or a + pole. can

As shown in FIG. 8 , the bare wire 190 is provided with a water leakage alarm circuit 400 for detecting water leakage by being connected to a power source. The water leak alarm circuit 400 has an advantage that it can be maintained at low cost because current does not flow when there is no water leakage as shown in FIG. 8A .

In the water leak alarm circuit 400, as shown in FIG. 8A, when water leaks in the lower part of the floor member in contact with the room floor and water comes into contact between the exposed bare wires 190, a current flows and the water leak detection unit 410 detects this. As shown in FIG. 8b, when the water leak detection unit 410 detects a current, the amplification unit 420 amplifies it, and the control unit 430 controls the driving signal generator 440 to generate an alarm through the alarm unit 450. do. In addition, the control unit informs the concerned person of the occurrence of water leakage through a mobile phone or a monitor through the interface unit 460, so that the water leakage can be repaired at an early stage.

In the above, a preferred embodiment of the hot water floor for heating according to the present invention has been described, but the present invention is not limited thereto. , which is also within the scope of the present invention.

40: Euro connector
52: insulation rod,
54: insulation plate
100: floor member
101: Euro
102: joint
103: jamming groove
104: stumbling block
105: insertion groove
110: upper
112: upper surface
120: lower
122: bottom
140: a plurality of hot water flow paths
141: first hot water flow path
142: second hot water flow path
143: third hot water flow path
144: fourth hot water flow path
145: 5th hot water flow path
150: joint groove
160: fastening ring coupling groove
170: Eumgu
190: bare wire (leak detection)
200: cap member
210: connector
211: thread
220: hose clamp
230: protrusion
240: wedge support
240a : arrow turn
300: hose
400: water leak alarm circuit
410: leak detection unit
420: amplification unit
430: control unit
440: alarm drive signal generator
450: alarm unit
460: interface unit

Claims (12)

A plurality of flooring members 100 are arranged adjacent to each other, and a plurality of hot water flow paths 140 are formed in a longitudinal direction inside the flooring member 100 in parallel, and are coupled to both ends of the flooring member 100 . In the hot water floor for heating in which a plurality of hot water flow paths 140 are communicated with each other by the cap member 200 and the hot water supplied from the flow path connection pipe 40 is circulated,
The floor member 100, the cap member 200, and the flow path connection pipe 40 are arranged in a straight line at the same height on a plane,
Some of the hot water flow paths 140 do not supply hot water, and only the other hot water flow channels supply hot water.
The upper part 110 of the floor member 100 is made of a heat transfer member made of carbon powder or carbon fiber having high thermal conductivity, and the lower part 120 is made of a heat insulating member that blocks heat transfer,
One to five of the floor members 100 are made of one floor module M, and each floor module M is integrally molded and formed.
Each floor module (M) connects a floor member having a large number of hot water flow paths to the hose side 300 for supplying hot water to the boiler so that the flow rate is slow, and the receiving hose side is connected to a floor member having a small hot water flow path to increase the flow rate. It is circulated so that the temperature can be evenly distributed,
A pair of bare wires 190 are semi-buried in parallel on both sides of the bottom surface of the floor member 100 or each floor module M, and the bare wires 190 are adjusted according to the width of the floor member 100 . to construct a circuit in which the middle bare wire is commonly used as a - or + pole by manufacturing three wires,
The bare wire 190 is provided with a water leakage alarm circuit 400 that detects water leakage by being connected to power, and the water leakage alarm circuit 400 is provided on both sides of the bottom surface of the floor member 100 or each floor module M. A pair of bare wires 190 are semi-buried in parallel, power is connected to both sides of the plurality of bare wires 190 to detect water leakage, and when there is no water leakage, no current flows,
In the water leak alarm circuit 400, when water comes into contact with the bare wires 190 exposed due to leakage under the floor member in contact with the floor, a current flows and the water leak detection unit 410 detects this, and the water leak detection unit ( When the 410 detects a current, the amplification unit 420 amplifies it, the control unit 430 controls the driving signal generator 440 to generate an alarm through the alarm unit 450 , and the control unit generates an alarm through the interface unit 460 . ) to notify the concerned person of the occurrence of a leak through a mobile phone or monitor, so that it can be repaired at an early stage. delete The method of claim 1,
The hot water flow path 140 of the floor member 100 is formed of five, but the 1st, 3rd, and 4th hot water flow paths do not supply hot water, and only the 2nd, 5th or 1st, 4th hot water flow channels supply hot water. Hot water floor for heating, characterized in that the structure. 4. The method of claim 3,
The hot water floor for heating, characterized in that when the cap member (200) is combined with the floor member (100), a tapered wedge support part (240) inserted into the third hot water flow path (143) is integrally formed. The method of claim 1,
The hot water floor for heating, characterized in that the cap member (200) is formed in one for each floor module (M). delete The method of claim 1,
Hot water floor for heating, characterized in that any one of a cypress wood pattern film, a copper foil plate, and an aluminum foil plate is attached to the upper surface of the upper part (110). 8. The method of claim 7,
The hot water floor for heating, characterized in that the bottom surface (122) of the floor member is coated with a thermal barrier material. The method of claim 1,
Joint grooves 150 are formed at both corners of the floor member 100 or each module M, and a “ㅛ”-shaped joint hole is formed between the joint grooves 150 of adjacent floor members 100. Hot water floor for heating, characterized in that the insertion and installation (170). delete The method of claim 1,
The hot water floor for heating, characterized in that the floor modules (M) are arranged in combination in an even number. delete

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