JP2001193950A - Heating system and its execution method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hot-water floor-heating system that can be executed easily and can carry out heating uniformly. SOLUTION: A double hose 6 is laid in a recessed groove 2 of a panel 1 where a heat exchanger plate 3 is provided on an upper surface. One ends of a pair of hose single substances 6a and 6b composing the double hose 6 are mutually connected. The other ends of the hose single substances 6a and 6b are set to inflow and outflow parts 9 and 10 of hot water, respectively, thus allowing hot water to mutually flow in an opposite direction in the hose single substances 6a and 6b, canceling the temperature difference between one end side and the other of the hose single substances 6a and 6b, and hence making temperature distribution nearly uniform in the entire double hose 6.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating system used for floor heating, roof snow melting, road snow melting and the like, and a construction method thereof, and more particularly to a heating system utilizing hot water flow and a construction method thereof.

[0002]

In a hot water type floor heating apparatus, a plurality of grooves are formed on the upper surface of a panel made of urethane foam and arranged under the floor, and a heat medium flow pipe is formed in the grooves. It is known that one hose is piped in a zigzag shape. Also, below the hose on the top of the panel,
There is also one in which an aluminum plate for heat conduction is interposed. Further, one end of the hose is an inflow portion into which hot water as a heat medium supplied from a boiler as a heat medium source flows, and the other end is an outflow portion for returning hot water to the boiler. Then, warm water supplied from the boiler passes through the hose, and the heat of the warm water in the hose is transmitted to the flooring and the tatami mat through the aluminum plate, thereby performing floor heating.

As described above, when hot water passes through the hose, the heat of the hot water is gradually removed, so that the temperature of the hot water in the hose is lower on the outflow side than on the inflow side. . For this reason, the temperature of the floor to be heated is also lower on the outflow side than on the inflow side, and there has been a problem that the temperature of the floor becomes uneven.

As means for solving such a problem,
For example, it is conceivable to provide a plurality of hoses and pass hot water through these hoses in different directions. However, if a plurality of hoses are provided, there is a problem that the construction is troublesome.

An object of the present invention is to solve such a problem, and an object of the present invention is to provide a heating system which can be easily installed and can perform uniform heating, and a method of installing the same.

[0006]

According to a first aspect of the present invention, there is provided a heating system for heating by passing a heat medium through a heat medium flow pipe provided along a heating surface. As the heat medium flow pipe, a composite hose in which a plurality of hoses are arranged and joined is used, and a heat medium source and a pipe for passing a heat medium in opposite directions to each hose of the composite hose are provided.

[0007] By passing the heat medium from the heat medium source to the heat medium flow pipe, the heating surface is heated to perform heating. At this time, the difference in temperature between the one end side and the other end side of each hose unit can be offset by passing the heat medium in the opposite direction to each of the unit hoses of the composite hose forming the heat medium flow pipe, and the temperature can be made uniform. Becomes possible.

According to a second aspect of the present invention, in the heating system according to the first aspect of the present invention, a double hose in which a pair of single hoses is arranged and joined is used as the composite hose, and one end of each of the two hoses is connected to each other. The other end of one of the hoses is used as a heat medium inflow portion, and the other end of the other hose is used as a heat medium outflow portion.

The heat medium flowing into the single hose from the inflow portion at one end of the single hose of the double hose flows into the single hose from the other end of the double hose,
The hose flows out from an outlet at the same end as the inlet of the hose. That is, the heat medium flows in opposite directions in both hoses, thereby canceling the difference in temperature between the one end and the other end of the hose alone, and the temperature distribution becomes substantially uniform in the entire double hose.

A third aspect of the present invention is the heating system according to the first aspect of the present invention, wherein a double hose in which a pair of single hoses is arranged and joined is used as the composite hose. One end is used as an inflow portion for the heat medium, the other end of the same hose is used as an outflow portion for the heat medium, and the other hose alone is used as an inflow portion for the heat medium. At the same time, the opposite end of the same hose unit is used as a heat medium outlet.

Therefore, the heat medium that has flowed into the single hose from the inflow portion at one end of the single hose of the double hose flows out from the outflow portion at the other end of the single hose. On the other hand, in the other hose unit, the heat medium flowing into the hose unit from the inflow part at the end corresponding to the end of the one hose unit on the outflow part side is opposite to the hose unit on the opposite side. Out of the outlet at the end of the. That is, the heat medium flows in opposite directions in both hoses, thereby canceling the difference in temperature between the one end and the other end of the hose alone, and the temperature distribution becomes substantially uniform in the entire double hose.

According to a fourth aspect of the present invention, in the heating system according to any one of the first to third aspects, the composite hose is piped in a concave groove formed in the upper surface of the panel, and the upper surface of the panel and the flow of the heat medium are distributed. The tube was covered with a heat storage plate.

Since the heat of the heat medium passing through the heat medium flow pipe is stored in the heat storage plate, the efficiency of heating is increased.

According to a fifth aspect of the present invention, there is provided the method for constructing a heating system according to any one of the first to fourth aspects, wherein the composite hose is connected to a hose storage portion while a single hose is connected to the hose. A plurality of single hoses are separated from each other on the end side of the composite hose, and the separated single hoses are connected to each other or connected to another pipe.

In this way, a plurality of hoses forming a composite hose only at a portion necessary for connection are separated from each other,
In other parts, the hose can be easily routed by piping the composite hose to the hose storage portion while the hose alone is in the joined state.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of a heating system and a construction method thereof according to the present invention will be described below with reference to FIGS. The heating system according to the present embodiment forms a floor heating device. Reference numeral 1 denotes a panel provided along a floor surface in a house, which is a heating surface.
Is made of urethane foam having excellent heat insulating properties.
On the upper surface of the panel 1, a plurality of parallel concave grooves 2 are formed as hose storage portions. Also, 3
Is a heat transfer plate. The heat transfer plate 3 is made of an aluminum plate or a copper plate having excellent heat conductivity, and is disposed on the panel 1. The heat transfer plate 3 is formed with a plurality of parallel linear gutters 4 having concave grooves on the upper side, and these gutter parts 4 are fitted into the concave grooves 2 of the panel 1, respectively.

Reference numeral 6 denotes a double hose as a composite hose forming a heat medium flow pipe which is piped along the floor of the room,
The double hose 6 is formed by joining a pair of flexible hoses 6a and 6b in parallel with each other, and the joint 7 of the hoses 6a and 6b can be relatively easily separated. ing. The double hose 6 is arranged in a zigzag manner in the gutter 4 of the heat transfer plate 3 on the panel 1. Also, both hoses 6a, 6b of the double hose 6
Are connected to each other as a connection part 7 so that both hoses 6a and 6b form one hose as a whole, but the other end of one hose 6a is made of a heat medium. It is the inflow section 9 of a certain hot water, and the other hose alone
The other end of 6b is an outlet 10 for hot water.

Reference numeral 11 denotes a boiler as a heat medium source. The boiler 11 passes hot water as a heat medium through the double hose 6. Reference numerals 12 and 13 denote hose headers forming pipes. The hose headers 12 and 13 are formed by projecting a plurality of hose connection portions 15 on the side surface of the main pipe portion 14. The hose headers 12 and 13 include a supply-side hose header 12 connected to a hot water supply port 16 from the boiler 11 and a boiler 11.
Hose header 13 connected to the hot water return port 17 to
The inflow portion 9 at the end of the one hose unit 6a is connected to the hose connection portion 15 of the supply side hose header 12, and the other hose unit 6b is connected to the hose connection portion 15 of the return side hose header 13. Is connected to the outflow section 10 at the end.

On the heat transfer plate 3 on the panel 1,
Heat storage plate 21 made of heat storage ceramics or bricks
Is placed. The heat storage plate 21 covers the entire upper surface of the heat transfer plate 3 and thus also covers the double hose 6. Further, a flooring 22 is formed on the upper surface of the heat storage plate 21 so as to form a floor surface in the room of the house.

In the construction, especially when piping the double hose 6, the double hose 6 is basically connected to the inside of the gutter portion 4 of the heat transfer plate 3 on the panel 1 while the pair of hoses 6a and 6b are basically joined. Pipe in a zigzag pattern. In addition, a pair of hoses 6a and 6b are separated by a required length at the end of the double hose 6, and one end of each of the hoses 6a and 6b is connected to each other, and the other end of the hoses 6a and 6b is connected to a hose header. Connect to 12, 13. The hoses 6a and 6b may be separated before or after the double hose 6 is connected to the panel 1.

Next, the operation of the above configuration will be described. At the time of heating, hot water supplied from the boiler 11 passes through the supply port 16 and the supply-side hose header 12, flows into the one hose unit 6a from the inflow part 9, passes through the hose unit 6a, and The hose 6a flows into the other hose body 6b from the end opposite to the inflow section 9 and passes through the inside of the hose body 6b, flows out of the outflow section 10 at the same end as the inflow section 9, and It returns to the boiler 11 through the return hose header 13 and the return port 17.

As described above, when hot water passes through the hose 6, the heat of the hot water is transmitted to the heat transfer plate 3, further transmitted from the heat transfer plate 3 to the heat storage plate 21, and the heat is stored in the heat storage plate 21. . The floor heating is performed by this heat. And boiler 11
The temperature is adjusted by the intermittent supply of hot water from. For example, a cycle in which the boiler 11 is operated for 30 minutes, stopped for 5 minutes, and further operated for 20 minutes is repeated.

According to the configuration of the above embodiment, the heat medium flow pipe is a double hose 6, and the ends of a pair of hoses 6a and 6b forming the double hose 6 are connected to each other.
The open end of one of the hoses 6a is defined as a hot water inflow section 9,
Since the open end of the other hose 6b is the hot water outflow section 10, the hot water flows through the hoses 6a and 6b in opposite directions. When the hot water passes through the hoses 6a and 6b, the heat of the hot water is gradually removed, so that the temperature of the hot water in the hoses 6a and 6b is higher than that of the inflow portion 9 in the outflow portion 10a.
Although the side is lower, the hot water flows through the hoses 6a, 6b in opposite directions to each other, so that the temperature difference between one end and the other end of the hoses 6a, 6b is offset. That is, the inflow section 9 and the outflow section 10 located on the same end side of both hoses 6a and 6b are the highest temperature section and the lowest temperature section, respectively, and the opposite end section is the middle temperature section. Therefore, the temperature distribution becomes substantially uniform in the entire double hose 6. Therefore, uniform floor heating can be performed.

[0024] The heat medium flow pipe is a pair of hoses alone.
Since it consists of a double hose 6 with 6a and 6b arranged side by side,
Workability is the same as when one hose is used, and work is easy. That is, a pair of hoses 6a and 6b are separated from each other only at a part necessary for connection, and the other part is connected to the hose 1 by piping the double hose 6 to the panel 1 with the hoses 6a and 6b joined. 6 can be easily arranged.

Further, since the heat storage plate 21 made of heat storage ceramics or bricks is provided so as to cover the heat transfer plate 3 and the double hose 6 on the panel 1, heat supplied from hot water is stored in the heat storage plate 21. By suppressing useless heat dissipation, heating efficiency can be improved. That is, boiler 11
In the intermittent operation of, the stop time can be extended.

Next, a second embodiment of the present invention will be described with reference to FIG.
This will be described with reference to FIG. Parts corresponding to those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.
In the second embodiment, the ends of a pair of hoses 6a and 6b forming a double hose 6 are not connected to each other,
One end of 6a and the other end of the other hose unit 6b are connected to the supply-side hose header 12 to be hot water inflow portions 9a and 9b, respectively, and the inflow portions 9a and 9b of both hose units 6a and 6b are connected.
The end opposite to 9b is connected to the return hose header 13 to form hot water outlets 10a and 10b, respectively. In addition,
At the time of construction, especially when piping the double hose 6, the pair of hoses 6a and 6b are basically joined together.
A double hose 6 is piped in a zigzag manner into the gutter 4 of the heat transfer plate 3 on the panel 1. Further, the pair of hoses 6a and 6b are cut off at a required length at the end side of the double hose 6, and each end of the hoses 6a and 6b is connected to the hose headers 12 and 13.

Therefore, the hot water supplied from the boiler 11 passes through the supply port 16 and the supply side hose header 12 and flows into the hoses 6a and 6b from the inflow portions 9a and 9b located on the opposite sides. After passing through the hoses 6a and 6b, they flow out of the outflow portions 10a and 10b, respectively, and further return to the boiler 11 through the return hose header 13 and the return port 17. That is, the hot water is separately supplied to both the hoses 6a and 6b, respectively, but the hot water flows in opposite directions in the hoses 6a and 6b. When the hot water passes through the hoses 6a and 6b, the heat of the hot water is gradually removed,
The temperature of the hot water in each hose 6a, 6b
The outlets 10a and 10b are lower than the outlets 9a and 9b, but the hot water flows through the hoses 6a and 6b in opposite directions.
The difference in temperature between the one end side and the other end side of the hoses 6a and 6b is canceled out, and the temperature distribution becomes substantially uniform in the entire double hose 6. Therefore, uniform floor heating can be performed.

It should be noted that the present invention is not limited to the above embodiment, and various modifications can be made. For example,
In the above embodiment, the double hose 6 is described as one system, but it is of course possible to provide a plurality of systems of double hoses. In the above embodiment, the heat storage plate 21 made of heat storage ceramics or bricks is provided to cover the panel 1 and the hose 6, but the heat storage plate 21 is not essential. Further, in the above-described embodiment, an example in which the present heating system is applied to floor heating is described. However, the present invention can be applied to general heating such as roof snow melting and road snow melting.

[0029]

According to the heating system of the first aspect of the present invention, a composite hose in which a plurality of hoses are arranged and joined is used as a heat medium flow pipe, and the heat medium is applied to each of the individual hoses of the composite hose in opposite directions. Since the heat medium source and the piping are provided, uniform heating is possible while maintaining ease of construction.

According to the heating system of the second aspect of the present invention, one end of a pair of hoses forming a double hose as a composite hose is connected to each other, and the other end of one of the hoses is connected to a heat medium. As the inflow part and the other end of the other hose unit as the heat medium outflow unit, the temperature difference between the one end side and the other end side of the hose unit is offset, and the temperature distribution in the entire double hose is reduced. It can be made almost uniform and can provide uniform heating.

According to the heating system of the third aspect of the present invention, one end of one of the pair of hoses forming a double hose which is a composite hose is used as a heat medium inflow portion, The other end of the hose unit serves as the outlet for the heat medium, the end of the other hose unit on the outlet side of the one hose unit serves as the inlet for the heat medium, and the opposite end of the same hose unit. Is used as the outlet for the heat medium, so that the temperature difference between one end and the other end of the hose unit can be canceled out, the temperature distribution in the entire double hose can be made almost uniform, and uniform heating can be achieved. .

According to the heating system of the fourth aspect of the present invention, the composite hose is piped into the concave groove formed on the upper surface of the panel, and the upper surface of the panel and the heat medium flow pipe are covered by the heat storage plate. Efficiency can be increased.

Further, according to the construction method of the heating system according to the fifth aspect of the present invention, the composite hose is connected to the hose storage section while the single hose is joined, and a plurality of single hoses are connected at the end of the composite hose. The hoses are separated from each other, and the separated hoses are connected to each other or connected to other pipes, so that the hoses can be easily routed and the construction can be facilitated.

[Brief description of the drawings]

FIG. 1 is a schematic plan view showing a first embodiment of a heating system of the present invention.

FIG. 2 is an exploded perspective view of a part of the above.

FIG. 3 is a partial cross-sectional view of the same.

FIG. 4 is a schematic plan view showing a second embodiment of the heating system of the present invention.

[Explanation of symbols]

 1 Panel 2 Concave groove (Hose storage section) 6 Double hose (Composite hose, Heat medium flow pipe) 6a Hose alone 6b Hose alone 9 Inflow 9a Inflow 9b Inflow 10 Outflow 10a Outflow 10b Outflow 11 Boiler (Heat Medium source) 12 Supply-side hose header (piping) 13 Return-side hose header (piping) 21 Heat storage plate

Claims (5)

[Claims] 1. A heating system in which heating is performed by passing a heat medium through a heat medium flow pipe arranged along a heating surface, wherein the heat medium flow pipe uses a composite hose in which a plurality of hoses are arranged and joined. A heating system comprising a heat medium source and a pipe for allowing a heat medium to pass through each of the single hoses of the composite hose in opposite directions. 2. A double hose comprising a pair of hoses arranged side by side and joined together as said composite hose. One end of each of said two hoses is connected to each other, and the other end of one of said hoses is connected to a heat medium inlet. 2. The heating system according to claim 1, wherein the other end of the other hose is used as an outlet for the heat medium. 3. A double hose in which a pair of single hoses are arranged and joined as the composite hose, and one end of one of the single hoses is used as a heat medium inflow portion, and the same single hose is used. The other end of the hose is the outlet of the heat medium, the end of the other hose on the outlet side of the one hose unit is the inlet of the heat medium, and the opposite end of the same hose unit is the heat medium. The heating system according to claim 1, wherein the outflow portion is provided. 4. The panel according to claim 1, wherein the composite hose is provided in a groove formed in an upper surface of the panel, and the upper surface of the panel and a heat medium flow pipe are covered with a heat storage plate. The heating system according to claim 1. 5. The method for constructing a heating system according to claim 1, wherein the composite hose is piped to a hose storage section while a single hose is in a joined state, and the composite hose is connected to the hose. A method for constructing a heating system, characterized in that a plurality of hoses are separated from each other on the end side, and the separated hoses are connected to each other or connected to other pipes.