JP2008107080A - Floor heating system - Google Patents

Abstract

There is provided a floor heating system capable of sufficiently circulating and circulating hot water to each floor heating panel even when a large number of floor heating panels are installed.
[Solution]
Hot water from the outlet 9 of the heat source unit 1 is hot water piping 10, header 11, each hot water piping 20, each indoor separate header 22, each hot water piping 25, each floor heating panel 30, hot water piping 28, indoor separate header 27. The hot water pipe 26, the header 12, the hot water pipe 13, and the auxiliary pump 14 flow in this order. A part of the return warm water discharged from the auxiliary pump 14 flows in the order of the hot water pipe 15, the return port 2, the pipe 3, the circulation pump 4, the heat exchanger 5, the pipe 7, the outlet 9, and the hot water pipe 10. The remaining part of the return warm water flows directly into the warm water pipe 10 via the bypass line 16, joins the warm water from the outlet 9, and flows toward the header 11.
[Selection] Figure 1

Description

  The present invention relates to a floor heating system that performs floor heating by circulating hot water from a heat source device such as a boiler to a floor heating panel.

  In the floor heating system, in general, it is connected to a heat source device having a hot water heating means, a hot water outlet and a hot water return port, and a hot water outlet and return port of the heat source device, through the heat source device. A hot water pipe for circulating hot water, a floor heating panel in which the hot water pipe is arranged in a serpentine shape, and a heat pump, a hot water pipe, and a circulation pump for circulating hot water to the floor heating panel. The hot water is distributed to the floor heating panel through the hot water piping.

  Examples of the prior art of this type of floor heating system include a hot water supply and heating system described in Patent Document 1, a hot water heater described in Patent Document 2, a floor heating system described in Patent Document 3, and the like.

  In Patent Document 1, hot water is supplied to a heat source device by a circulation pump, hot water from the heat source device is supplied to a floor heating panel by a forward line, and hot water from the floor heating panel is supplied via a return line and the circulation pump. It is returned to the heat source machine. The floor heating panel side and the forward line rather than the return line circulation pump communicate with each other via the primary heat transfer pipe of the heat exchanger and the pipe connected thereto.

  A three-way valve is provided at the connection between the pipe and the forward line. This three-way valve is controlled to be switched alternatively or not to flow hot water from the heat source device to the floor heating panel or to the heat transfer pipe. In addition, the primary side heat transfer tube is connected to the forward line on the upstream side of the pump in the return line.

  In Patent Document 2, the hot water in the hot water tank is circulated and circulated to the floor heating panel with a circulation pump, and a part of the hot water discharged from the circulation pump is separated and heated by a heat exchanger, and returned to the hot water tank. I have to.

In Patent Document 3, a hot water supply header and a return hot water header are attached to a water heater with a built-in circulation pump, and hot water is circulated from each header to a plurality of floor heating panels via a hot water supply forward pipe and a return pipe.
JP 2002-257365 A Japanese Patent Application Laid-Open No. H5-272764 Japanese Patent Laid-Open No. 10-170005

  In the floor heating system that circulates hot water from the heat source unit to the floor heating panel via the hot water pipe, if the number of floor heating panels is large, the circulation pump installed in the heat source unit can supply enough hot water to each floor heating panel. Since it cannot be supplied, an auxiliary circulation pump may be provided in the hot water pipe.

  However, even if the auxiliary circulation pump is provided in this way, the flow rate of water supplied to the floor heating panel may not be sufficiently increased due to the large water flow resistance of the heat source unit itself.

  An object of this invention is to provide the floor heating system which can fully circulate and distribute warm water to each floor heating panel, even when many floor heating panels are installed.

  The floor heating system of the present invention is connected to a hot water heating means, a hot water outlet and a hot water return port, and a hot water outlet and return port of the heat source machine. A floor provided with a hot water pipe for circulation, a floor heating panel in which the hot water pipe is arranged in a meandering manner, and a heat pump, a hot water pipe, and a circulation pump for circulating hot water through the floor heating panel. In the heating system, the hot water pipe includes a bypass for circulating hot water between the hot water pipe connected to the outlet of the hot water of the heat source machine and the hot water pipe connected to the return port without passing through the heat source machine. It is characterized by comprising a line.

  This bypass line is separate from the minimum flow line that may be provided in the heat source machine.

  In the present invention, the bypass line is preferably configured so that hot water having a flow rate equal to or higher than the flow rate flowing through the heat source machine flows. preferable.

  In the present invention, a bypass line for circulating hot water without passing through the heat source machine is provided between the hot water pipe connected to the hot water outlet of the heat source machine and the hot water pipe connected to the return port. A part of the hot water returned from the panel is sent to the hot water piping connected to the outlet through this bypass line without passing through the heat source machine. For this reason, the discharge flow rate of the circulation pump in the heat source machine and the flow rate flowing through the bypass line are superimposed and flow through the hot water piping toward the floor heating panel. Therefore, even if the number of floor heating panels is large, it is possible to sufficiently distribute hot water to each floor heating panel.

  In this invention, warm water can be fully distribute | circulated to each floor heating panel by making the flow volume which passes a bypass line into the same amount or more as the flow volume which passes a heat-source machine, Preferably it is 1-10 times.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, what is described below is an example of embodiments of the present invention, and the present invention is not limited to the following description unless it exceeds the gist. It is not limited. FIG. 1 is a system diagram of a floor heating system according to an embodiment.

  In the floor heating system according to this embodiment, a plurality (n) of floor heating panels are laid in each of a plurality of (m) rooms of the building, and the circulation pump 4 is provided. The hot water is circulated from the heat source device 1 through a pipe and an auxiliary circulation pump 14.

  The heat source machine 1 circulates the return warm water from the return port 2 in the order of the pipe 3, the circulation pump 4, the heat exchanger 5, the pipe 7, and the outlet 9, and in this heat exchanger 5, warm water is heated by the heat from the burner 6. It is configured to warm.

  The pipes 3 and 7 are communicated with each other by a minimum flow line 8. This minimum flow line 8 is provided in the heat source unit 1, and even when the circulation pump 4 is operated in a no-load state in which all of the valves 21 described later are closed, water is supplied to the pipes 3 and 7 and the minimum flow line 8. It is for circulating through a flow line.

  An outgoing header 11 is connected to the outgoing port 9 via a hot water pipe 10. A header 12 on the return side is installed in parallel with the header 11. The header 12 is connected to the return port 2 via a hot water pipe 13, an auxiliary circulation pump 14 and a hot water pipe 15. A hot water pipe 15 connecting the auxiliary circulation pump 14 and the return port 2 and the warm water pipe 10 on the forward side communicate with each other via a bypass line 16.

  In this embodiment, the bypass line 16 comprises a straight pipe or a curved pipe that is at least partially loosely curved. The bypass line 16 is not provided with any valves such as a flow rate adjusting valve or an on-off valve, and is configured so that the flow resistance of the hot water flowing from the return side hot water pipe 15 to the forward side hot water pipe 10 is small. Yes.

  In this embodiment, the outgoing hot water pipe 10 constitutes the outgoing main line (main pipe). The return-side hot water pipes 13 and 15 constitute a return main line.

  The upstream header 11 is connected to the upstream ends of a plurality (m) of outgoing hot water pipes 20. The return side header 12 is connected to the downstream ends of the same number (m) of return side hot water pipes 26 as the hot water pipes 20. Usually, the number of building rooms (m) is 1 to 10, preferably 1 to 5. In the figure, (1) and (m) are added to the reference numerals 20 and 26 to indicate that there are m hot water pipes 20 and 26, respectively. These hot water pipes 20 and 26 are made of, for example, a copper pipe, an aluminum composite pipe, a cross-linked polyethylene pipe, and the like, and are led around the ceiling or floor of the building. In addition, the material of piping is not limited to this.

  The downstream end of each hot water pipe 20 and the upstream end of each hot water pipe 26 are connected to indoor headers 22 and 27 installed in each room of the building, respectively.

  In each room of this building, a plurality of (n) floor heating panels 30 (30 (1) to 30 (n)) are installed, and each floor heating panel 30 (1) to 30 (n) These are connected to the indoor separate headers 22 and 27 via the warm water pipe 25 on the outgoing side and the warm water pipe 28 on the return side, respectively. The number (n) of the floor heating panels per room is usually 1 to 10, preferably 2 to 6, although it depends on the size of the room. These hot water pipes 25 and 28 are made of a crosslinked polyethylene pipe or the like, but the material is not limited to this.

  In this embodiment, the hot water pipes 20 and 26 are first branch lines (branch pipes), and the pipes 25 and 28 are second branch lines (branch pipes).

  Each hot water pipe 20 is provided with a flow rate adjusting valve 21 so that the flow rate is adjusted by an indoor remote controller 24 for adjusting the floor heating temperature provided in each room. The same number of indoor remote controllers 24 as the number of rooms (m) are provided.

  In the floor heating system configured as described above, when a floor heating operation switch (not shown) is turned ON, the circulation pump 4, the auxiliary circulation pump 14 and the burner 6 are operated, and the hot water from the outlet 9 is the hot water as the main pipe. Pipe 10, header 11, each hot water pipe 20 that is the first branch pipe, each indoor separate header 22, each hot water pipe 25 that is the second branch pipe, each floor heating panel 30, and hot water pipe 28 that is the second branch pipe The indoor separate header 27, the hot water pipe 26 as the first branch pipe, the header 12, the hot water pipe 13 as the main pipe, and the auxiliary circulation pump 14 flow in this order.

  A part of the return warm water discharged from the auxiliary circulation pump 14 is the hot water pipe 15, the return port 2, the pipe 3, the circulation pump 4, the heat exchanger 5, the pipe 7, the outlet 9, and the main pipe as the main pipe. It flows in the order of the hot water piping 10. The remaining portion of the return warm water discharged from the auxiliary circulation pump 14 flows directly into the hot water pipe 10 as the main pipe via the bypass line 16, joins the hot water from the outlet 9, and flows toward the header 11.

  As described above, the auxiliary circulation pump 14 is provided, and the hot water pipes 15 and 10 as the main pipes are communicated with each other by the bypass line 16, and a part of the return warm water returned through the hot water pipe 13 as the main pipe is Since it is made to distribute | circulate directly from the bypass line 16 to the hot water piping 10 which is main piping, it becomes possible to increase the hot water supply flow volume which goes to the header 11 from the hot water piping 10, and to distribute | circulate sufficient amount of warm water to each floor heating panel 30. .

  In addition, when the floor heating panel 30 and the surrounding floor are almost sufficiently heated and the floor heating system is in a steady operation state, the temperature of the warm water returning to the return port 2 is about 55 to 60 ° C. It is. This return warm water is heated by the heat exchanger 5 and sent out from the outlet 9 as warm water of about 70 to 75 ° C.

  Therefore, even when a part of the return warm water discharged from the auxiliary circulation pump 14 is joined from the bypass line 16 to the hot water pipe 10 without heating, the warm water pipe 10 passes through the header 11 and the like to the floor heating panel 30. The temperature of the supplied hot water is as high as about 60 to 70 ° C.

  If the bypass line 16 is omitted, even if the auxiliary circulation pump 14 is provided, the flow resistance of the heat exchanger 5 in the heat source machine 1 is particularly large, and the hot water sent from the hot water pipe 10 is large. The flow rate cannot be increased, and sufficient hot water cannot be supplied to the floor heating panel in the large floor heating system.

The pipe inner diameters of the hot water pipes 10, 13, and 15 that are main pipes are usually 16 to 30 mm, the pipe inner diameters of the hot water pipes 20 and 26 that are the first branch pipes are usually 13 to 20 mm, and the second branch pipes. The inner diameters of the hot water pipes 25 and 28 are usually 7 to 10 mm. The pipe inner diameter of the bypass line 16 is preferably 1.0 to 2.0 times the pipe inner diameter of the hot water pipes 10, 13 and 15 as the main pipes, and the pipe inner diameter of the minimum flow line is the main pipe. The inner diameter of the hot water pipes 10, 13, 15 is preferably 0.1 to 0.6 times the inner diameter.

  In the present invention, when the floor heating system is in a steady operation state, the flow rate (volume flow rate) flowing through the bypass line 16 is the flow rate of the pipe 3, the heat exchanger 5, and the pipe 7 in the heat source unit 1 (of the heat source unit). The length and the pipe diameter of the bypass line 16 are preferably set so as to be 1 to 10 times, particularly 1 to 3 times the flow rate). The pipe inner diameter of the minimum flow line is usually 3 to 10 mm, preferably 3 to 5 mm, and the pipe inner diameter of the bypass line is usually 10 to 30 mm, preferably 15 to 25 mm. The inner diameter of the bypass line is usually 2 to 8 times, preferably 4 to 7 times the inner diameter of the minimum flow line. Further, in order to increase the flow rate of the bypass line 16 as described above, the bypass line 16 may be a straight tube or at least a part of a curved tube that is gently curved, and is not provided with a valve or the like that provides a flow resistance. desirable. However, a flow rate adjusting valve or an on-off valve may be provided at the branch line between the bypass line 16 or the hot water pipes 15 and 10 as the main pipe and the bypass line 16 (not shown). When the flow rate adjustment valve is provided in the bypass line 16, the hot water flow rate of the hot water pipe 15 can be appropriately distributed to the bypass line 16 and the heat source unit 1.

  The location where the circulation pump 4 is provided is not limited to the location shown in FIG. For example, in FIG. 1, the circulation pump 4 may be provided at a location where the auxiliary circulation pump 14 is provided. Even in such a case, the flow rate of the bypass line 16 can be adjusted by providing the flow rate adjusting valve and the on-off valve.

  In addition, as said floor heating panel 30, a groove | channel is provided in the upper surface of the plate-shaped heat insulating material which consists of a foaming synthetic resin etc., for example, a hot water tube is drawn in this groove | channel, and aluminum etc. are provided on the upper surface of this base. However, the present invention is not limited to this.

As the floor heating panel 30, various types that are already on the market can be used. In an ordinary floor heating panel, the area is about 0.8 to 10 m ² , the inner diameter of the tube is about 4 to 7 mm, particularly about 5 to 6 mm, and the tube length is about 10 to 70 m, especially about 20 to 50 m. is there. Hot water is circulated at a flow rate of about 0.5 to 1.5 L / min, for example, about 1 L / min, for one floor heating panel. In this case, the water pressure loss of one floor heating panel is about 20 to 40 KPa, for example, about 30 KPa.

  Although the auxiliary circulation pump 14 is provided in the return-side hot water pipe 13 in the above embodiment, the auxiliary circulation is provided in the outward-side hot water pipe 10 (however, the header 11 side from the connection point of the bypass line 16). A pump 14 may be installed. However, in this case, there is a possibility that negative pressure may be generated in the pipe of the heat source unit 1 and the heat exchanger 5 on the upstream side of the auxiliary circulation pump 14, so that the return side hot water pipe 13 as shown in FIG. It is preferable to provide it. Although an auxiliary circulation pump may be provided in both the hot water pipes 13 and 10, it is preferable to provide only in the hot water pipe 13 because of high cost.

According to the floor heating system of the present invention, it is possible to circulate hot water of 25 to 50 L / min per system, of which 15 to 40 L / min is passed through the bumper line without passing through the heat source unit. It is possible to make it the quantity which circulates warm water to a heating panel, and the floor heating using 100-400 m < ² > in the total area of a floor heating panel is attained.

It is a systematic diagram of the floor heating system concerning an embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Heat source machine 2 Warm water return port 3 Piping 4 Circulation pump 5 Heat exchanger 6 Burner 7 Piping 8 Minimum flow line 9 Warm water return port 10 Hot water piping 11 and 12 headers 13 and 15 composing the return main line Constructing hot water piping 14 Auxiliary circulation pump 16 Bypass line 20, 25, 26, 28 Hot water piping composing branch line 30 Floor heating panel

Claims (9)

A heat source unit having heating means for warm water, a warm water outlet and a warm water return port;
A hot water pipe for circulating hot water through the heat source machine, connected to the outlet and return port of the hot water of the heat source machine;
A floor heating panel in which the hot water pipes are arranged in a serpentine shape;
A floor heating system comprising a heat pump, a hot water pipe, and a circulation pump for circulating hot water to the floor heating panel,
The hot water pipe is provided with a bypass line for circulating hot water between the hot water pipe connected to the hot water outlet of the heat source machine and the hot water pipe connected to the return port without going through the heat source machine. Floor heating system characterized by.   The floor heating system according to claim 1, further comprising a minimum flow line in the heat source unit that communicates the piping on the outlet side and the piping on the return side with respect to the heating means in the heat source unit.   The floor heating system according to claim 1 or 2, wherein a circulation pump is provided in the heat source unit.   The floor heating system in any one of Claims 1 thru | or 3 which provided the circulation pump further in the hot water piping before the bypass line connected with the return port of the hot water of a heat source machine.   The floor heating system according to claim 1 or 2, wherein a circulation pump is provided in a hot water pipe before the bypass line connected to a hot water return port of the heat source unit.   The hot water pipe has a plurality of branch pipes branched according to the number of rooms to be floor-heated via a main pipe and a header, and the branch pipes are arranged on the floor heating panel. The floor heating system in any one of.   The floor heating system according to claim 6, wherein a pipe inner diameter of the bypass line is 1.0 to 2.0 times a main pipe inner diameter of the hot water pipe.   The floor heating system according to claim 2, wherein the pipe inner diameter of the bypass line is 2 to 8 times the pipe inner diameter of the minimum flow line.   The floor heating system according to any one of claims 1 to 8, wherein the hot water flow rate in the bypass line is configured to be 1 to 10 times the hot water flow rate in the heat source unit.

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