JP5547467B2 - Heating system - Google Patents

Description

  The present invention relates to an indoor heating system using two types of heating devices.

As this type of heating system, a system disclosed in Patent Document 1 is known. This heating system includes a floor heating device (first heating device), an air conditioner (second heating device), an infrared unit, and a controller.
The floor heating device is a device capable of heating an indoor floor surface with a heating fluid. An air conditioner is a device that can supply hot air indoors and has an infrared receiver.
The controller is an operating device installed indoors, and includes a mechanism for controlling the floor heating device, a mechanism for controlling the air conditioner (signal transmission control mechanism), and connection means (such as a connector and a terminal block).

In the known heating system, the above-described controller is connected to both the infrared unit and the floor heating device via a signal line.
Then, the floor heater is operated by the controller and the air conditioner is operated via the infrared unit. Thereby, the room can be efficiently heated in conjunction with the floor heating device and the air conditioner.

JP 2008-82586 A

By the way, the controller of a well-known technique is what is called an exclusive article, and has a different structure from a general purpose controller (controller which operates each heating apparatus independently).
For this reason, the controller of the known technology tends to be complicated or large in size, and it is not a configuration that can be easily adopted in consideration of manufacturing costs and the like.

Further, the configuration of the known technology has not been a configuration that can flexibly respond to user requests. For example, when a controller (exclusive product) of a known technique is to be supplied, the following countermeasures can be considered for a user who does not require a mechanism for controlling an air conditioner (signal transmission control mechanism).
(I) Supply another controller without a signal transmission control mechanism.
In this case, it is necessary to separately prepare a controller (dedicated product) of a known technique, and an investment in its manufacturing equipment is required. Also, when the production volume of dedicated products is small, the investment efficiency deteriorates.
(Ii) Do not connect the infrared unit.
In this case, even a user who does not need the signal transmission control mechanism must bear the manufacturing cost and the like related to the mechanism and connection means (connector, terminal block, etc.).
The present invention has been devised in view of the above-described points, and a problem to be solved by the present invention is to link the first heating device and the second heating device by utilizing a general-purpose configuration as much as possible.

As means for solving the above problems, a heating system according to a first aspect of the present invention includes a first heating device capable of heating an indoor floor surface with a heating fluid, a second heating device capable of supplying warm air into the room, A first controller that operates the single operation of the heating device and a second controller that operates the single operation of the second heating device with infrared rays .
In this type of configuration, it is desirable that the first heating device and the second heating device can be linked by using a general-purpose configuration (for example, an existing controller) as much as possible.

Here, in the present invention, the first heating device includes a radiator that heats the indoor floor surface with the heating fluid, and an outdoor heat source unit that supplies the heating fluid to the radiator, and includes the first controller and the heat source unit. It is the structure which exchanges the operation information of a 1st heating apparatus by bidirectional | two-way communication between.
In the present invention, the control device is interposed in an outdoor signal line connecting the first controller and the heat source unit, and the operation information of the first heating device exchanged between the first controller and the heat source unit can be acquired. The signal line is connected to the indoor stationary infrared unit that operates the second heating device with infrared rays . Moreover, an infrared unit has a receiving part which receives the operation information of the 2nd heating apparatus from a 2nd controller, and a transmission part which operates a 2nd heating apparatus independently.
Therefore by the control device actuates the second heating device via an infrared unit based on the first heating apparatus or operation information of the first heating device from the first controller to together acquires the operation information of the first heating device, It was set as the structure which acquires the operation information of a 2nd heating apparatus from an infrared unit, and operates a 1st heating apparatus .
In the present invention, the first heating device and the second heating device are interlocked by the control device. For this reason, both heating apparatuses can be made to interlock | cooperate, without requiring the big change of a general purpose structure (for example, 1st controller).

Moreover, the heating system of 1st invention connects the above-mentioned control apparatus with a signal wire to both a 1st controller and a heat source machine, and the operation information of the 1st heating apparatus exchanged between a 1st controller and a heat source machine is carried out. Acquired. According to the present invention, since the control device can acquire a wider range of information, the first heating device and the second heating device can be linked more accurately.

Heating system of a second invention has a heating system of the first invention, the first heating device, a supply pipe member to heat the fluid of the heat source machine heat radiator, a valve member provided in the tube member. And it is the structure which adjusts the heating fluid amount supplied to a heat radiator by opening / closing of a valve member (for example, adjusting the opening / closing time of a valve member, and changing the heating load of a 1st heating apparatus).
Therefore, in the present invention, the opening / closing information of the valve member is included in the operation information of the first heating device. For this reason, the second heating device can be operated more accurately by the control device based on the opening / closing information of the valve member.

The heating system of the third invention is the heating system of either the first invention or the second invention, and the operation information of the first heating device described above includes a heating operation mode, a test operation mode, an anti-freezing operation mode, and the like. Other operating modes are included.
Therefore, the control device causes the second heating device to perform a heating operation based on the heating operation mode of the first heating device, and causes the second heating device to operate in a non-heating operation state (for example, non-heating) based on another operation mode of the first heating device. Operating state). Thus, the room can be heated more accurately by interlocking the second heating device based on each operation mode of the first heating device.

A heating system according to a fourth aspect of the present invention is the heating system according to any one of the first to third aspects of the present invention, and the operation information of the first heating device includes settings of the first controller such as a set temperature and a set capability stage. .
Therefore, the control device determines the settings of the second heating device such as the set temperature and the set air volume based on the settings of the first controller. Thus, the room can be heated more efficiently by determining the setting of the second heating device corresponding to the setting of the first controller.

The heating system according to a fifth aspect is the heating system according to any one of the first to fourth aspects , wherein the control device operates the first heating device via the first controller.

According to 1st invention of this invention, a 1st heating apparatus and a 2nd heating apparatus can be made to interlock | cooperate using a general purpose structure as much as possible. According to the first invention, the system configuration is more convenient. And according to 2nd invention-5th invention, a 1st heating apparatus and a 2nd heating apparatus can be interlock | cooperated more correctly.

It is the schematic of a heating system. It is the schematic of the heating system of Embodiment 2. It is a figure which shows the test result of the comparative example 1, (a) is a graph of energy consumption, (b) is a graph which shows indoor temperature distribution. It is a figure which shows the test result of Example 1, (a) is a graph of energy consumption, (b) is a graph which shows indoor temperature distribution. It is a figure which shows the test result of Example 2, (a) is a graph of energy consumption, (b) is a graph which shows indoor temperature distribution.

Hereinafter, embodiments for carrying out the present invention will be described with reference to FIGS.
In the house of FIG.1 and FIG.2, the range enclosed with the broken line is set as indoor RI, the part remove | deviated from a broken line is set as outdoor RO, and code | symbol RF is attached | subjected to an indoor floor surface. In each figure, a symbol UP is given above the house and a symbol DW is given below the house. In each figure, the signal line SL of the existing configuration is indicated by a broken line, and the newly added signal line SL is indicated by a solid line.

[Embodiment 1]
The heating system of this embodiment has the 1st heating apparatus 10, the 2nd heating apparatus 20, the 1st controller 30, the 2nd controller 40, the infrared unit 50, and the control apparatus 60 (refer FIG. 1). Details of each member will be described later).
The first heating device 10 is a device that can heat the indoor floor surface RF with a heating fluid, and the first controller 30 can operate the operation (single operation). The second heating device 20 is a device capable of supplying warm air to the room RI, and the operation (single operation) can be operated by the second controller 40 or the infrared unit 50.
In the present embodiment, the first heating device 10 and the second heating device 20 are linked to efficiently heat the room RI (see [Test Example] described later). In this type of configuration, it is desirable that the first heating device 10 and the second heating device 20 can be linked using a general-purpose configuration (for example, a general-purpose configuration controller) as much as possible.
Therefore, in the present embodiment, the first heating device 10 and the second heating device 20 are interlocked by the control device 60 described later. Hereinafter, each configuration will be described in detail.

(First heating device)
The 1st heating apparatus 10 has the heat radiator 12, the heat source machine 14, the pipe member (the 1st pipe member 16f, the 2nd pipe member 16s), and the valve member 18 (refer FIG. 1).
The radiator 12 (panel shape) has a heat retaining portion 13 (tubular) through which a heated fluid can flow, and can be disposed below the indoor floor surface RF. The heat source unit 14 is a member that supplies a heating fluid to the radiator 12 and can be disposed in the outdoor RO.

The heat source device 14 of the present embodiment includes a housing 14 a, an internal configuration thereof (a heat exchanger 14 b, a combustion burner 14 c, an internal pipe 14 d, a circulation pump 14 e, a control unit 14 f), and a fuel supply path 19. The casing 14a is a substantially rectangular box (hollow shape), and the lower side can be opened or closed or opened. The fuel supply path 19 is a pipe member that supplies fuel (fossil fuel) to the combustion burner 14c in the heat exchanger 14b.
The heat exchanger 14b and the combustion burner 14c are disposed in the middle of the internal pipe 14d. The fluid (water, brine, etc.) in the internal pipe 14d can be heated by the combustion burner 14c in the heat exchanger 14b. One end of the internal pipe 14d communicates with the circulation pump 14e, and the other end of the internal pipe 14d opens at the bottom of the housing 14a. The valve member 18 is connected to the internal pipe 14d (the other end).
The opening and closing of the valve member 18 can be controlled by the control unit 14f. The control unit 14f of the present embodiment is disposed on the lower side of the housing 14a and can change the opening / closing setting of the valve member 18 from the outside (the opening / closing setting of the valve member 18 is relatively easy).

And a heating fluid is distribute | circulated between the heat radiator 12 and the heat-source equipment 14 by the 1st pipe member 16f and the 2nd pipe member 16s. In the present embodiment, the circulation pump 14e (one end of the internal pipe 14d) and the heat retaining unit 13 are connected by the first pipe member 16f. Further, the valve member 18 (the other end of the internal pipe 14d) and the heat retaining portion 13 are connected by the second pipe member 16s.
In the present embodiment, the supply amount of the heating fluid to the radiator 12 can be adjusted by the opening / closing operation of the valve member 18. At this time, the heating load of the first heating device 10 can be changed by adjusting the opening / closing time of the valve member 18.

(First controller)
The first controller 30 is a member that independently operates the operation of the first heating device 10 (a typical general-purpose controller), and can be arranged in the room RI.
And the 1st controller 30 of this embodiment is connected with the heat source machine 14 (control part 14f) via the communication line SL via the control apparatus 60 mentioned later, The operation information (exchange information) of the 1st heating apparatus 10 Can be exchanged by two-way communication.
As the operation information (communication message) of the above-described bidirectional communication, operation start and stop (including error determination), operation mode (other operation modes such as heating operation mode, test operation, and freeze prevention operation), valve member 18 Examples include opening / closing information, supply power, driving power of the circulation pump 14e, and setting information (setting temperature, setting capability stage, etc.) of the first controller.

(Second heating device)
The 2nd heating apparatus 20 has the heat radiator 22 (1st receiver 22a), refrigerant | coolant piping 24a, 24b, and the outdoor unit 26 (refer FIG. 1). The radiator 22 (substantially rectangular) is a member capable of supplying warm air, and can be disposed on the upper wall surface of the room RI. The outdoor unit 26 is a member that generates warm air in the radiator 22 and can be disposed in the outdoor RO.
The 2nd heating apparatus 20 of this embodiment can receive the infrared rays of the below-mentioned 2nd controller 40 (1st transmission part 40b) or the infrared unit 50 (2nd transmission part 50b) in the 1st receiving part 22a. . And by the action | operation of the 2nd heating apparatus 20, warm air can be made with the refrigerating cycle formed with the radiator 22, the outdoor unit 26, and refrigerant | coolant piping 24a, 24b, and it can be supplied to indoor RI from the radiator 22.

(Second controller)
The 2nd controller 40 is a member which operates the operation | movement of the 2nd heating apparatus 20 independently (it is a typical general purpose controller), and has the 1st transmission part 40b.
The 1st transmission part 40b is a member which converts the control command (operation information) of the 2nd heating apparatus 20 into an infrared signal, for example, can be formed by arrange | positioning an LED lamp in a transparent housing.
By operating the second controller 40, the second heating device 20 can be operated alone. The shape and dimensions of the second controller 40 are not particularly limited, but it is preferable that the second controller 40 has an outer dimension that can be held by the user.
Examples of the operation information (communication message) described above include start and stop of operation (including error determination), operation mode (other operation modes such as heating operation mode, trial operation and anti-freezing operation), set temperature, and set air volume. .

(Infrared unit)
The infrared unit 50 is an indoor stationary member that operates the second heating device 20 with infrared rays, and includes a second reception unit 50a and a second transmission unit 50b. The second receiver 50a and the second transmitter 50b may each be a single mechanism or a simple integrated mechanism.
The infrared unit 50 of this embodiment can operate the 2nd heating apparatus 20 independently by the 2nd transmission part 50b. Moreover, the infrared unit 50 can acquire the operation information (command) of the second heating device 20 from the second controller 40 by the second receiver 50a.
In addition, although the installation location of the infrared unit 50 is not specifically limited, It is preferable to attach to the height position where transmission / reception with the 2nd heating apparatus 20 is smooth.

(Control device)
The control device 60 is a separate member from the above-described existing configuration (20, 30, 40, 50), and can be retrofitted to the existing configuration (see FIG. 1).
The control device 60 of the present embodiment includes a mechanism for controlling the first heating device 10 (first control mechanism not shown), a mechanism for controlling the second heating device 20 (second control mechanism not shown), and a communication message. A mechanism for analyzing (analyzing mechanism not shown) and a configuration for connecting a plurality of signal lines SL (not shown connectors and terminal blocks) are provided. For example, the analysis mechanism can determine the operation mode of each heating device, or can count the number of opening and closing of the valve member 18.

In the present embodiment, the control device 60 is connected to the infrared unit 50 through the signal line SL. Next, the control device 60 is connected to the first heating device 10 (the control unit 14f) and the first controller 30 (between both devices) by signal lines. In this embodiment, the man-hour of the installation work of the control device 60 is simplified by interposing the control device 60 in the signal line SL (existing signal line SL) between the first heating device 10 and the first controller 30. it can. Further, since the control unit 14f is disposed on the lower side of the housing 14a, the signal line connection with the control device 60 is relatively easy.
And the control apparatus 60 is interposed between the control part 14f and the 1st controller 30, and can receive the bidirectional | two-way communication (communication telegram) between both the members 14f and 30. FIG.

[Interlocking of both heating devices]
In the present embodiment, the control device 60 acquires the operation information of the first heating device 10 from the control unit 14 f (first heating device 10) or the first controller 30. Further, the control device 60 operates the second heating device 20 via the infrared unit 50 based on the operation information of the first heating device 10. Then, the control device 60 links the first heating device 10 and the second heating device 20 to efficiently heat the room RI (see [Test Example] described later).
For this reason, according to this embodiment, the 1st heating apparatus 10 and the 2nd heating apparatus 20 can be interlocked using a general-purpose structure as much as possible (without requiring the substantial change of the existing structure of each controller). As described above, according to the heating system of the present embodiment, the first heating device 10 and the second heating device 20 are smoothly interlocked to achieve both the formation of a comfortable indoor heating space and the energy saving of the heating system. it can.

Moreover, in this embodiment, the control apparatus 60 can acquire the operation information (communication message) of the 1st heating apparatus 10 exchanged between the 1st controller 30 and the heat-source equipment 14. FIG. Thus, since the control apparatus 60 can acquire more extensive information, the 1st heating apparatus 10 and the 2nd heating apparatus 20 can be linked more correctly.
For example, in the present embodiment, there is a mode in which the first controller 30 does not transmit operation information to the heat source unit 14 and the first heating device 10 operates according to a command from the heat source unit 14 (test operation, freeze prevention operation, etc.).
Therefore, the control device 60 causes the second heating device 20 to perform the heating operation based on the heating operation mode of the first heating device 10. Further, the control device 60 sets the second heating device 20 to a non-heating operation state (for example, a non-operation state or a state in which the operation is performed in another similar operation mode) based on another operation mode of the first heating device 10. Can do.
As described above, by interlocking the second heating device 20 based on each operation mode of the first heating device 10, the room can be heated more accurately.

Moreover, in this embodiment, the heating fluid amount of the heat radiator 12 can be adjusted by opening and closing the valve member 18 (for example, the heating load of the first heating device 10 can be changed by adjusting the opening and closing time of the valve member 18).
Therefore, in the present embodiment, the control device 60 can operate the second heating device 20 more accurately based on the opening / closing information of the valve member 18 (the heating fluid supply amount of the first heating device 10 and the like).
For example, the control device 60 can estimate the heating load of the first heating device 10 based on the opening / closing information of the valve member 18. Thereby, the 1st heating apparatus 10 and the 2nd heating apparatus 20 are made to interlock | cooperate appropriately, and a room | chamber interior can be heated efficiently.

In the present embodiment, the opening / closing cycle of the valve member 18 (from the start of valve opening to the start of the next valve opening) can be set constant. At this time, the control device 60 can determine the operating state of the first heating device 10 based on the opening / closing cycle of the valve member 18.
That is, when the opening / closing cycle of the valve member 18 is shorter than normal, the control device 60 determines that the operation (heating operation) of the first heating device 10 is continued even when the valve member 18 is in the closed state. can do.
Further, the control device 60 can determine that the operation (heating operation) of the first heating device 10 has stopped when the elapsed time from the previous valve opening operation of the valve member 18 is longer than the normal opening / closing cycle. . In addition, when the elapsed time from the previous valve opening operation of the valve member 18 to the next valve opening operation is longer than the normal opening / closing cycle, the control device 60 starts the operation (heating operation) of the first heating device 10. Can be judged.

Further, in the present embodiment, the control device 60 determines the operation state (operation mode, set temperature, air volume, etc.) of the second heating device 20 based on the settings of the first controller 30 (set temperature, setting capacity stage, etc.). can do.
Thus, by determining the setting of the second heating device 20 corresponding to the setting of the first controller 30, the room can be heated more efficiently. Therefore, according to the present embodiment, the primary energy consumption can be reduced (energy saving can be achieved) while maintaining the spatial temperature distribution in the head-and-bottom heat type room.

Moreover, in this embodiment, the infrared unit 50 has the 2nd receiving part 50a. For this reason, the control device 60 can obtain the operation information (communication message) of the second heating device 20 from the infrared unit 50 via the second controller 40. Then, the first heating device 10 can be operated by the control device 60 based on the operation information of the second heating device 20. At this time, the control device 60 may be configured to operate the first heating device 10 via the first controller 30.
In the present embodiment, the first heating device 10 and the second heating device 20 can be linked by the control device 60 by operating either the first controller 30 or the second controller 40 (more convenient). System configuration).
Thereby, even when the user operates the first controller 30 or the second controller 40, a comfortable air-conditioned space can be obtained and energy saving can be realized.

[Embodiment 2 (reference example) ]
Since the basic structure of the second embodiment is almost the same as that of the first embodiment, a detailed description is omitted by assigning corresponding reference numerals to common structures and the like.
In this embodiment, the 2nd heating apparatus 20 (control part 14f) and the 1st controller 30 are connected by communication line SL (existing signal line SL) (refer FIG. 2). In addition, the control device 60 was connected to the first heating device 10 (the control unit 14f) via the signal line SL without being connected to the first controller 30.
And the operation information of the 1st heating apparatus 10 is acquired from the control part 14f by the control apparatus 60. FIG. Next, the second heating device 20 is linked via the infrared unit 50 based on the operation information of the first heating device 10.
According to the present embodiment, since the control device 60 only needs to receive communication from the control unit 14f, the analysis mechanism can be simplified. Moreover, the 1st heating apparatus 10 and the 2nd heating apparatus 20 can be interlocked | linked by the control apparatus 60, utilizing the communication line SL (existing structure) of the 1st controller 30 and the 1st heating apparatus 10 as it is.

[Modification]
In the modification, at least one of the first controller 30 and the second controller 40 can be remotely operated through an external line such as a telephone line (having a home automation function). And the control apparatus 60 acquires the driving | operation command of one controller by remote operation, and makes the 1st heating apparatus 10 and the 2nd heating apparatus 20 interlock | cooperate.
According to this modification, the first heating device 10 and the second heating device 20 can be interlocked by remote control (a more convenient system configuration).

[Test example]
Hereinafter, although this embodiment is described based on a test example, the present invention is not limited to the test example.
In this test, the primary energy consumption and indoor temperature distribution of the heating system shown in FIG. 1 were measured. This test was conducted in a test room (heat insulation performance Q value [2.7 W / m ² · K]) having a height of 2.4 m, a width of 3.6 m, and a depth of 3.6 m. The 2nd heating apparatus was arrange | positioned in the height position of 2000 mm from the indoor floor surface (refer FIGS. 3-5).
As Comparative Example 1 (reference), only the first heating device was used, and the set temperature was 20 ° C. (see FIG. 3).
Moreover, in Example 1, the setting temperature of the 1st heating apparatus was 20 degreeC, and the setting temperature of the 2nd heating apparatus was set to 17 degreeC (refer FIG. 4). Moreover, in Example 2, the setting temperature of the 1st heating apparatus was 20 degreeC, and the setting temperature of the 2nd heating apparatus was set to 20 degreeC (refer FIG. 5).

Then, the primary energy consumption (kcal) of the first heating device was calculated by totaling the amount of gas used (gas) of the first heating device and the power consumption (auxiliary power) of the first heating device. As auxiliary power, the power consumption of a gas heat source for hot water supply and heating (corresponding to the heat source 14 in FIG. 1) was measured. In this test, the primary energy consumption was measured every predetermined time from the start of heating.
Further, the temperature distribution in the vertical direction at the center of the room between 6 hours and 7 hours from the start of heating was measured. At this time, the temperature of the height positions of 400 mm, 800 mm, 1200 mm, 1600 mm, 2000 mm, and 2400 mm was measured with the indoor floor surface set to 0.

[Results and discussion]
With reference to FIGS. 3-5, compared with the comparative example 1, the primary energy consumption of the 1st heating apparatus was able to be reduced suitably in the heating system of Example 1 and Example 2. FIG. In particular, in the heating system of Example 2, it was possible to form an ideal indoor temperature distribution while suitably reducing the primary energy consumption.
From this, according to the heating system of Example 1 and Example 2, it turns out that the formation of a comfortable indoor heating space and the energy saving of a system can be made compatible by interlocking a 1st heating apparatus and a 2nd heating apparatus. It was.

The heating system of the present embodiment is not limited to the above-described embodiment, and can take other various embodiments.
(1) In this embodiment, although the structure of the 1st heating apparatus 10, the 2nd heating apparatus 20, and the infrared unit 50 was illustrated, it is not the meaning which limits the structure of these apparatuses. And this heating system is widely applicable to a general purpose 1st heating apparatus, a 2nd heating apparatus, and an infrared unit. For example, a first heating device that electrically heats the fluid can be used. Moreover, the installation position of a 1st heating apparatus, a 2nd heating apparatus, and an infrared unit can be changed suitably.
(2) In the present embodiment, the configurations of the first controller 30 and the second controller 40 are exemplified, but the configuration of these devices is not intended to be limited. That is, this heating system can be widely applied to general-purpose first controllers and second controllers.

(3) In the second embodiment, the control device 60 is connected to the control unit 14f via a signal line. Unlike this, the control device 60 can be connected to the first controller 30 without connecting the signal line to the control unit 14f.
(4) Moreover, in this embodiment, the example which determines the operation state of the 2nd heating apparatus 20 based on the setting of the 1st controller 30 by the control apparatus 60 was demonstrated. Unlike this, the operation state of the first heating device 10 can also be determined by the control device 60 based on the setting of the second controller 40.

DESCRIPTION OF SYMBOLS 10 1st heating apparatus 12 Radiator 13 Heat retention part 14 Heat source machine 16f 1st pipe member 16s 2nd pipe member 18 Valve member 19 Fuel supply path 20 2nd heating apparatus 22 Radiator 22a 1st receiving part 26 Outdoor unit 30 1st Controller 40 Second controller 40b First transmitter 50 Infrared unit 50a Second receiver 50b Second transmitter 60 Controller RF Indoor floor RI Indoor RO Outdoor SL Signal line

Claims (5)

A first heating device capable of heating an indoor floor surface with a heating fluid, a second heating device capable of supplying warm air into the room, a first controller for operating a single operation of the first heating device, and a second heating device In a heating system having a second controller that operates the single operation with infrared rays ,
The first heating device includes a radiator that heats the indoor floor surface with a heating fluid, and an outdoor heat source unit that supplies the heating fluid to the radiator, and between the first controller and the heat source unit, the first heating unit It is a configuration to exchange device operation information by bidirectional communication,
While the control device is interposed in an outdoor signal line connecting the first controller and the heat source device, it is possible to obtain the operation information of the first heating device exchanged between the first controller and the heat source device, and the second heating Connect the signal line to the indoor infrared unit that operates the device with infrared rays .
The infrared unit has a reception unit that receives operation information of the second heating device from the second controller, and a transmission unit that operates the second heating device alone,
The controller actuates the second heating device via an infrared unit based on the first heating apparatus or the first operating information Heating device together acquires the operation information from the first controller first heating device, the A heating system for operating the first heating device by obtaining operation information of the second heating device from the infrared unit . The heating system according to claim 1, wherein
The first heating device has a pipe member that supplies the heating fluid of the heat source unit to the heat radiating body, and a valve member that is provided on the pipe member, and adjusts the amount of heating fluid supplied to the heat radiating body by opening and closing the valve member. Configuration,
The heating system in which the opening / closing information of the valve member is included in the operation information of the first heating device . In the heating system according to claim 1 or 2,
The operation information of the first heating device includes a heating operation mode and other operation modes such as a test operation mode and a freeze prevention operation mode,
A heating system that causes the second heating device to perform a heating operation based on the heating operation mode of the first heating device and causes the second heating device to enter a non-heating operation state based on another operation mode of the first heating device. . In the heating system in any one of Claims 1-3,
The operation information of the first heating device includes the settings of the first controller such as the set temperature and the setting capacity stage,
The heating system which determines the setting of 2nd heating apparatuses, such as setting temperature and a setting air volume, by the control apparatus based on the setting of a 1st controller . In the heating system according to any one of claims 1 to 4,
A heating system in which the control device operates the first heating device via the first controller .

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