JPH11173633A - Heating system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform efficient heating by an air conditioner and a floor heater. SOLUTION: When a hot water air conditioner is set to automatic operation mode, this heating system compares the indoor temperature with the set temperature (steps 304-310) while detecting the indoor temperature by a radiation sensor (step 302). Hereby, it is set to level 1 (step 312) until the indoor temperature reaches the set temperature, so normal control is performed, but the limitation of heating capacity becomes larger in stages by the indoor temperature getting over the set temperature and further by the temperature difference becoming larger (steps 314-318), and when the temperature difference becomes t3 or over, it is set to level 5 (step 320), and the heating by a hot water air conditioner, not to speak of floor heating, is also stopped.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner for heating and cooling a room, and more particularly, to a heating system for heating a room using both an air conditioner and a floor heating device.

[0002]

2. Description of the Related Art An air conditioner for indoor air conditioning includes:
In addition to a general air conditioner (air conditioner) that performs a cooling and heating operation by a refrigeration cycle using a refrigerant, there is a hot water air conditioner that performs a cooling operation by a refrigeration cycle and performs a heating operation by using hot water (hereinafter referred to as “hot water”). "Air conditioner").

In a hot water air conditioner, during a heating operation, water is heated by a heat source unit (heat source unit) provided outside to generate hot water, and this hot water is exchanged with a hot water heat exchanger provided in an indoor unit. By circulating, the air blown into the room from the indoor unit is heated and heated.

There are floor heating devices such as an electric floor heating carpet and a floor heating mat for heating by supplying hot water into a hot water tube laid on the floor in the room. Today, air conditioners are widely used, and air conditioners and floor heating devices are often used together.

Some floor heaters using hot water use hot water generated by a heat source unit of a hot water air conditioner. That is, a heating system using hot water includes a combination of a hot water air conditioner and a floor heating mat. In such a heating system, the room can be simultaneously heated by the warm air blown from the floor surface and the indoor unit.

[0006]

However, even in such a heating system using the same heat source unit, the heating by the hot water air conditioner and the heating of the room by the floor heating mat are performed separately, so that the heating is performed. However, it is not always possible to perform efficient heating from the viewpoint of energy saving. In particular, the floor heating device itself is not subjected to detailed temperature control, especially in a floor heating mat using hot water, etc.
Although the upper limit of the temperature is set, the temperature of the hot water is substantially constant, so that the surface temperature changes according to the environmental temperature. When heating is performed in combination with an air conditioner (hot water air conditioner), the heating temperature of the floor heating mat increases.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned circumstances, and proposes a heating system in which an air conditioner can efficiently heat a room using a floor heating device and thereby can save energy. Aim.

[0008]

The invention according to claim 1 is
An air conditioner that heats the room to a set temperature by blowing air controlled by a heat exchanger provided in the indoor unit from the indoor unit, and a floor heating unit laid on the floor of the room. A floor heating device for heating from a surface, a temperature detection unit for detecting a temperature of a room heated by the air conditioner and the floor heating device, and a room detected by the set temperature of the air conditioner and the temperature detection unit. Limiting means for limiting at least the heating capacity of the floor heating device based on the temperature.

According to the present invention, at least the heating capacity of the floor heating device is limited based on the room temperature and the set temperature by using the limiting means. By controlling the heating capacity of the floor heating device according to the set temperature when the air conditioner performs the heating operation, it is possible to prevent the floor heating device from increasing the room temperature more than the set temperature.

By preventing the room temperature from rising more than the set temperature, energy can be saved, and efficient heating can be achieved.

The invention according to claim 2 is characterized in that it operates when the limiting means is set to automatic operation as an operation condition of the air conditioner.

According to the present invention, when the operation mode of the air conditioner is set to the automatic operation, the limiting means limits the heating capacity of the floor heating device. When the air conditioner is set to the automatic operation, it is a time when the room is set to maintain the set temperature for a long time. At this time, the room temperature is set by limiting the heating capacity of the floor heating device. Can be prevented from being kept higher than the set temperature.

The invention according to claim 3 is characterized in that the limiting means limits the heating capacity of the floor heating device in a plurality of stages according to a temperature difference between the room temperature and the set temperature.

According to the present invention, the heating capacity of the floor heating device is controlled in a plurality of stages according to the temperature difference between the set temperature and the room temperature. This makes it possible to obtain sufficient heating capacity until the temperature near the floor heated by the floor heating device approaches the set temperature, and the temperature near the floor greatly exceeds the set temperature. Can be prevented.

The invention according to claim 4 is characterized in that the temperature detecting means detects a temperature near a floor surface heated by the floor heating device.

According to the present invention, the temperature near the floor heated by the floor heating device is detected by the temperature detecting means. When heating is performed using a floor heating device, the room temperature is slightly lower than the temperature near the floor. If the floor surface is warmer than the room temperature, a comfortable feeling of heating can be obtained. For this reason,
By controlling the heating capacity of the floor heating device based on the temperature near the floor, the room can be efficiently and comfortably heated.

According to a fifth aspect of the present invention, the restricting means includes:
The heating operation of each of the floor heating device and the air conditioner is stopped when the room temperature becomes higher than the set temperature by a predetermined value or more during the heating operation.

According to the present invention, when the room temperature greatly exceeds the set temperature, the heating by the air conditioner is limited by stopping the air conditioner or the like. Generally, air conditioners
The heating capacity is controlled based on the room temperature and the set temperature, and the heating capacity is suppressed when the room temperature exceeds the set temperature. At this time, even when the room temperature detected by the temperature detecting means exceeds the set temperature, if the air conditioner performs the heating operation while suppressing the heating capacity, the room temperature may be further increased. The heating operation of the conditioner is substantially stopped.

Thus, it is possible to prevent the temperature at a height away from the floor surface from rising more than the set temperature, and to maintain the room temperature substantially at the set temperature.

[0020]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a schematic configuration of an air conditioner applied to the present embodiment. This air conditioner is a hot water air conditioner that performs heating using hot water (hereinafter, referred to as “hot water air conditioner 10”). The hot water air conditioner 10
It comprises an indoor unit 12 installed in a room to be air-conditioned and an outdoor unit 14 installed outdoors. A relay unit 20 for communication connected to the indoor unit 12 and the outdoor unit 14 is provided near the indoor unit 12. In addition, the outdoor unit 14 is connected to a floor heating mat 142 that is laid on the floor of the room air-conditioned by the indoor unit 12 to heat the room from the floor. Indoor unit 12 and floor heating mat 1
42 constitutes a hot water heating system 11 for heating.

The indoor unit 12 of the hot water air conditioner 10 has an indoor unit comprising an evaporator 16 which is a heat exchanger for refrigerant circulated by a refrigeration cycle and a radiator 18 which is a heat exchanger for hot water in which hot water is circulated. 22 are formed.
In addition, the evaporator 16 and the radiator 18 provided in the indoor unit 12 may be integrally connected.
They may be provided separately.

The outdoor unit 14 includes a refrigerant unit 24 forming a refrigeration cycle for circulating a refrigerant with the evaporator 16 of the indoor unit 22, and generates hot water and transmits the generated hot water to the radiator 18 of the indoor unit 22. The heat source unit 26 circulates between the heat source units. In addition, the outdoor unit 14 may be an integral type in which the refrigerant unit 24 and the heat source unit 26 are integrally accommodated in the same casing, or are separate types in which each is accommodated in a separate casing. Is also good. Further, the heat source unit 26 may use hot water for hot water supply for heating.

As shown in FIGS. 1 and 3, the evaporator 16 of the indoor unit 22 is connected to the refrigerant unit 24 via refrigerant pipes 28A and 28B. As shown in FIG. 3, in the refrigerant unit 24, the refrigerant pipes 28A,
One of the refrigerant pipes 8B (refrigerant pipe 28A) is connected to a valve 32. The valve 32 is connected to a compressor 40 via a muffler 34A and an accumulator 38. The compressor 40 is connected to a heat exchanger (condenser) 42 via a muffler 34B. The heat exchanger 42 is connected to a valve 48 via a capillary tube 44 and a strainer 46, and the other refrigerant pipe 28B is connected to the valve 48. Thereby, in the hot water air conditioner 10, a refrigeration cycle is formed between the indoor unit 22 and the refrigerant unit 24.

In the hot water air conditioner 10, when the operation mode is selected as the cooling mode or the dehumidification mode (dry mode), the compressor 40 is operated and the refrigerant is circulated. The refrigerant unit 24 is provided with a cooling fan 53 for cooling the heat exchanger 42 near the heat exchanger 42, and operates the cooling fan 53 as necessary to cool the heat exchanger 42. This prevents the condensation efficiency of the refrigerant from being reduced. In FIG. 3, the flow of the refrigerant is indicated by arrows.

The evaporator 16 of the indoor unit 22 is provided with a heat exchanger temperature sensor (not shown). In the hot water air conditioner 10, the temperature of the evaporator 16 is lower than a predetermined temperature during cooling operation (for example, 6.4). (C or less) so as to perform the cooling operation while controlling the capacity of the compressor 40.

The radiator 18 of the indoor unit 22 is connected to the heat source unit 26 of the outdoor unit 14 via, for example, flexible hot water pipes (hereinafter, referred to as "hot water tubes") 30A and 30B. One hot water tube 30A is
The hot water inlet nipple 56A of the heat source unit 26 is connected to the hot water inlet nipple 56A, and the other hot water tube 30B is connected to the hot water outlet nipple 56B of the heat source unit 26.

The hot water tube 30B is connected to the indoor unit 22.
Is connected to the hot water inlet nipple 66A of the
Is connected to the radiator 18 via the The hot water tube 30A is connected to the hot water outlet nipple 6 of the indoor unit 22.
6B is connected to the radiator 18.

In the heat source unit 26, the hot water outlet nipple 56B is connected to the hot water inlet nipple 56A via the hot water heat exchanger 64, the pump 62 and the pressure tank 60, whereby the indoor unit 22 and the hot water unit 26 are connected. A closed circulation path of hot water is formed between them.

The hot water unit 26 is provided with a gas burner 70 for generating hot water. The gas burner 70 is connected to the gas burner 70 from outside the machine via gas solenoid valves 180A and 180B and a gas proportional valve 182. Gas is supplied. The gas burner 70 heats the water in the hot water heat exchanger 64 by burning this gas to generate hot water for heating. The pressure tank 60 is connected to a drain tank 72 via a pressure cap 58, and discharges water (for example, tap water) circulating in the hot water circulation path via the drain tank 72.

In the heat source unit 26, when the water temperature (the temperature of the hot water) rises and the internal pressure becomes equal to or higher than a predetermined value (for example, 0.9 kg / cmU), the pressure valve of the pressure cap 58 is actuated. The hot water is discharged from the pressure relief port provided to the drain tank 72 to prevent the pressure in the pipe from rising, and when the temperature of the hot water decreases and the internal pressure becomes less than a predetermined value, the negative pressure valve is activated to operate the drain tank 72. To collect water from The water overflowing from the drain tank 72 is discharged from a drain pipe connection port.

When operating in the cooling mode or the dry mode, the hot water air conditioner 10
(Operation of hot water) is stopped, and the variable flow valve 68 is closed (operation step 0). On the other hand, during the heating operation (heating mode), the heat source unit 26
The gas burner 70 is ignited and the pump 62 is operated, and the variable flow valve 68 of the indoor unit 22 is opened. Thereby, the hot water is generated in the heat exchanger 64, and the generated hot water is circulated between the heat exchanger 64 and the radiator 18 of the indoor unit 22. The heat source unit 26 is provided with a high-temperature thermistor (not shown) between the hot-water heat exchanger 64 and the hot-water outlet nipple 56B, and a temperature detected by the high-temperature thermistor is about 80 ° C. (for example, about 80 ° C.). 82
° C) while circulating while controlling the temperature of the hot water. The opening degree of the variable flow valve 68 (operation step)
Is set according to the room temperature and the set temperature.

The indoor unit 22 is provided with a cross flow fan 90 for blowing air. Also, as shown in FIG. 2, the indoor unit 1 in which the indoor unit 22 is housed.
2 has a suction port 50 and an outlet 5
2 are provided. In the indoor unit 22, by operating the cross flow fan 90, the suction port 50
The air in the room is sucked in from the outlet 52 and is blown out from the outlet 52.
At this time, the temperature of the air sucked from the suction port 50 is controlled by passing through the evaporator 16 to the radiator 18 of the indoor unit 22, and the temperature-controlled air is blown out from the blowout port 52, so that the indoor air is blown out. Is air-conditioned. The outlet 52 is provided with upper and lower flaps 54 and left and right flaps (not shown), and the direction of temperature-controlled air blown from the outlet 52 is changed by the upper and lower flaps 54 and the left and right flaps.

As shown in FIG. 4, the indoor unit 22
Includes a microcomputer (hereinafter "microcomputer 100").
) Is provided. The control board 102 includes a power supply board 10
4. A power relay 110, a temperature fuse 112, a variable flow valve 6 together with a display board 106 and a switch board 108.
8. Fan motor 1 for driving cross flow fan 90
14. Louver motor 11 for controlling upper and lower flaps 54
6 are connected.

In the indoor unit 22, when AC power for operation is supplied to the power supply board 104, the AC power is converted into predetermined power by the power supply board 104 and supplied to the control board 102. The AC power supplied to the indoor unit 22 is supplied from the terminal plate 132 to the heat source unit 26 of the outdoor unit 14, and is supplied from the terminal plate 132 to the refrigerant unit 24 of the outdoor unit 14 via the power relay 110. You. That is, the operating water is always supplied to the hot water unit 26 similarly to the indoor unit 22, and the refrigerant unit 24
The operation is performed by the electric power supplied by turning on the power relay 110 according to the signal from the signal 02.

The control board 102 includes a heat exchange temperature sensor 118 for detecting the temperature of the evaporator 16, a humidity sensor 120 for detecting the indoor humidity, a hot water heat exchanger sensor 122 for detecting the temperature of the radiator 18, Gas shortage sensor 12
4 etc. are connected.

As shown in FIG. 4, the display substrate 106 is provided with display LEDs 128 and the like. As shown in FIG. 2, the display unit 82 is provided on the casing 36 of the indoor unit 12, and the display LED 1 on the display board 106 is provided.
28 and the like are arranged on the display unit 82 (not shown in FIG. 2). Thereby, the display LED 12 of the display unit 82
The operating state of the hot water air conditioner 10 (operating / stopping, operating mode, etc.) can be determined based on the lighting state of 8.

As shown in FIG. 4, a communication I / F board 134 is connected to the control board 102 of the indoor unit 22. To the communication I / F board 134, a control board (not shown) provided in the refrigerant unit 24 and a relay unit 20 described later are connected. An operation signal, an indoor temperature, and the like are input to the microcomputer 100 of the indoor unit 22 from the relay unit 20 described later via the communication I / F board 134. The microcomputer 100 controls the operation of the refrigerant unit 24 by performing serial communication with the refrigerant unit 24 via the communication I / F board 134.

In the hot water air conditioner 10, operating conditions such as an operation mode and a set temperature are set, and when an air conditioning operation is instructed, the indoor temperature becomes the set temperature while controlling the operating capacity based on the set temperature and the indoor temperature. Air-conditioning operation.
For example, when the heating operation is performed in the automatic operation mode, the heating capacity, the amount of blown air, the wind direction, and the like are controlled while predicting the change in the room temperature by fuzzy calculation. Thus, as shown in FIG. 7, the room temperature T _R is gradually approach the set temperature T _s, the room temperature T _R is the set temperature T predetermined temperature with respect to _S t ₀ (e.g. 0.5 ° C ) To maintain the indoor air-conditioning state. At this time, the room temperature T
_The heating capacity is controlled so that _R does not increase by more than a predetermined temperature (for example, 1 ° C.) from the set temperature T _S. The control of the air conditioning capacity of the indoor unit 22, the configuration of the refrigerant unit 24, and the control of the refrigerant unit 24 by serial communication can use a conventionally known configuration and method, and a detailed description thereof will be omitted in the present embodiment. In the hot water air conditioner 10, the indoor temperature is input from the relay unit 20. However, a temperature sensor for detecting the indoor temperature may be provided in the indoor unit 22.

As shown in FIG. 5, the heat source unit 26
Has a control board 1 equipped with a microcomputer (not shown).
74 are provided. In the control board 174,
Power transformer 176, hot water circulation pump (pump motor) 62, igniter 17 for igniting gas burner 70
8. Gas solenoid valves 180A and 180B for supplying combustion gas to the gas burner 70, a gas proportional valve 182, a fan motor 184 for air supply, and the like are connected. The control board 174 transforms the power supplied from the terminal plate 132 of the indoor unit 22 by the power transformer 176,
Electric power for driving the pump 62 and the like is obtained.

A high temperature thermistor 186 for measuring the temperature of the hot water sent from the hot water heat exchanger 64, an outside air temperature sensor 188 for detecting the outside air temperature, a rotation detector 190 for the fan motor 184, and the like are connected to the control board 174. Have been. The control board 174 generates hot water of a predetermined temperature while monitoring the operating state of each device in the heat source unit 26 with these sensors.

A temperature fuse 192, a high limit switch 194, and the like are connected to the control board 174, and a setting switch 200, a pump test terminal 196, and an operation monitoring terminal 198 for externally displaying an operation state and the like. A combustion lamp 202 that lights up when the gas burner 70 is ignited, a failure display LED 204 that displays an error code when a failure occurs, a maintenance switch 206, a secondary pressure adjustment volume 208, and the like are provided.

On the other hand, as shown in FIGS. 1 and 3, a floor heating mat 142 is connected to the heat source unit 26 as a floor heating unit, whereby the floor is heated by the heat source unit 26 and the floor heating mat 142. Heating device 14
0 is configured. The heat source unit 26 of the hot-water air conditioner 10 may be a floor heating unit provided with a hot-water pipe inside or below a floor plate in a room.

As shown in FIG. 3, the heat source unit 26
Has a hot water inlet nipple 56A and a hot water outlet nipple 56A.
B, a hot water inlet nipple 80A and a hot water outlet nipple 80B are provided side by side. A floor heating mat 142 is connected between the hot water inlet nipple 80A and the hot water outlet nipple 80B.

In the floor heating mat 142, for example, a warm water tube 146 is tightly woven in a mat 144 laid on the floor in a room. As shown in FIG. 3, in the floor heating mat 142, one end of the hot water tube 146 is connected to the hot water inlet nipple 84A, and the hot water tube 86A is connected to the hot water outlet nipple 80B of the heat source unit 26 via the thermal valve 76. The other end of the hot water tube 146 is connected to the heat source unit 26 by connecting the hot water tube 86B connected to the hot water outlet nipple 84B to the hot water inlet nipple 80A of the heat source unit 26. As a result, when the pump 62 operates, warm water is circulated in the floor heating mat 142 in response to opening and closing of the thermal valve 76, and the mat 144 is heated by the warm water.

As shown in FIG. 5, this thermal valve 78
Is connected to a control board 174 of the heat source unit 26, and the opening and closing of the board are controlled by the control board 174.

In the heat source unit 26, the floor heating mat 14
When the start of floor heating by the instruction 2 is instructed, the thermal valve 76 is opened and closed at regular time intervals to circulate hot water into the hot water tube 146 of the floor heating mat 142. Thereby, the mat 144 of the floor heating mat 142 is gradually heated. That is, the heat source unit 26 circulates hot water to the floor heating mat 142 at a preset duty ratio.

As shown in FIGS. 1 and 5, the heat source unit 26 has a signal line 148 from the floor heating mat 142.
Is connected. The signal line 148 is connected to a thermistor (not shown) for detecting the temperature of the mat 144 of the floor heating mat 142, and the heat source unit 26 detects that the temperature of the mat 144 has exceeded a predetermined value (for example, 31 ° C.). Is detected via the signal line 148, the thermal valve 76 is closed to stop the circulation of the hot water, thereby suppressing the temperature rise of the mat 144. That is, as shown in FIG. 8 (A), floor heating mat 142, at predetermined time intervals, perform heating by hot water supplied by the time S ₀ only intermittently Netsudoben 76 is turned on It has a general configuration. Thus, the temperature of the floor heating mat 142 (the surface temperature of the mat 144) is maintained at a temperature corresponding to the outside air temperature or the indoor temperature. In addition, the duty ratio at the time of controlling to turn on / off the thermal valve 76 is set in advance, and during normal control, floor heating is performed based on the set duty ratio.

Control board 17 of heat source unit 26
4, a communication I / F board 136 is provided, and the heat source unit 26 is connected to the relay unit 20 via the communication I / F board 136.

On the other hand, as shown in FIG. 6, the relay unit 20 includes a control board 1 having a microcomputer 150.
The communication I / F board 154 for data communication and the communication I / F board 156 for serial communication are connected to 52.
Further, a temperature detection board 158 and a receiving board 160 are provided in the relay unit 20, and these are connected to the control board 152.

The receiving board 160 is connected to the system remote controller 13.
An operation signal transmitted from 0 is received. That is, as shown in FIG.
0, a reception window 162 is formed.
By operating the system remote controller 130 toward 62, an operation signal transmitted from the system remote controller 130 is received by the receiving board 160.

The system remote controller 130 is used to operate / stop the hot water air conditioner 10, set the set temperature, set or switch the operation mode, set the direction and amount of the conditioned air blown from the outlet 52 of the indoor unit 12, and set the timer. In addition to the functions of a remote control switch used for a general air conditioner such as time setting during operation, etc., it also has a function of operating / stopping floor heating by the floor heating mat 142 and a function of operating the floor heating mat 142 such as temperature setting. It has become a multi-function type.

When the microcomputer 150 of the relay unit 20 receives the operation signal transmitted from the system remote controller 130, the microcomputer 150 derives an operation signal for air conditioning of the indoor unit 22 and the refrigerant unit 24 and the floor heating device 1 from the operation signal.
The operation signal for hot water heating for the heat source unit 40 and the heat source unit 26 is separated, and the operation signal for air conditioning is transmitted to the communication I / F board 156.
, And is transmitted to the indoor unit 22 by serial communication.

The microcomputer 150 of the relay unit 20
When the operation signal for hot water heating is separated from the received operation signal, the heat source unit 2 via the communication I / F board 154
Output to 6. At the same time, the microcomputer 150 inputs the heat source unit 26 and the operating state of the floor heating mat 142 using the heat source unit 26 from the control board 174 of the heat source unit 26 to the communication I / F board 154. In the relay unit 20, the operating state of the heat source unit 26 and the floor heating mat 142 is also sent to the indoor unit 22.

As described above, the microcomputer 100 of the indoor unit 22 performs the air conditioning operation based on the signal input from the relay unit 20. That is, during the heating operation of the hot water air conditioner 10, the heating operation is performed in consideration of the operation state of the heat source unit 26 and the floor heating device 140 input via the relay unit 20.

A radiation sensor 164 for detecting temperature from infrared rays is provided on the temperature detection board 158 of the relay unit 20.
Is provided. As shown in FIG. 2, the relay unit 20 is provided with a condenser lens 166, and an infrared ray emitted from an object to which the condenser lens 166 is directed according to the surface temperature is transmitted to the condenser lens 166. The radiation sensor 164 receives the light through the 166.

As the radiation sensor 164, an infrared sensor that detects infrared rays emitted from an object according to the surface temperature is used. The temperature detection board 158 sets the surface temperature of the object to be measured within an error range of 1 ° C. or less. Can be detected and output.

The microcomputer 150 of the relay unit 20 sends the temperature detected by the temperature detection board 158 to the indoor unit 22 together with an operation signal from the system remote controller 130 as the room temperature.

The condenser lens 166 of the relay unit 20
The hot water air conditioner 10 is directed to a position near a floor at a predetermined position (for example, a central portion) of an area to be air-conditioned by the hot water air conditioner 10 or a position at a predetermined height from the floor. The indoor temperature detected by this relay unit 20 is
Swing in a predetermined range to detect the temperature of many positions in the room, an average value of the detected temperatures and the like may be used as the room temperature, and the direction of the condenser lens may be set to a predetermined position set in advance. The temperature detected in a fixed state may be used as the room temperature.

In the heat source unit 26, the relay unit 20
The operation control is performed based on the operation signal sent from. At this time, the thermal valve 7 based on the set temperature of the floor heating mat 142 set by the system remote controller 130 and the surface temperature of the floor heating mat 142 detected by the relay unit 20.
By controlling the opening / closing (on / off) of the floor heating mat 6, the surface temperature of the floor heating mat 142 is set to the set temperature.

By the way, in the air conditioning system 11, when the heating by the hot water air conditioner 10 and the floor heating by the floor heating mat 142 are simultaneously selected, the heating is individually performed by the hot water air conditioner 10 and the floor heating mat 142, respectively. When the hot water air conditioner 10 is selected to be in the automatic operation mode, the relay unit 20 controls the heating capacity of the floor heating mat 142 based on the room temperature and the set temperature.

That is, the relay unit 20 changes the heating capacity of the floor heating mat 142 stepwise according to the set temperature set by the system remote controller 130 and the room temperature detected by the radiation sensor 164.

When floor heating by the floor heating mat 142 is set, the heat source unit 26 turns on / off the thermal valve 76 at a preset duty ratio. On the other hand, the relay unit 20 limits the heating time of the floor heating mat 142 by limiting the time during which the thermal valve 76 is turned on in accordance with the room temperature relative to the set temperature.

In the relay unit 20, the floor heating mat 14
Limit level of the second heating capacity is set in a plurality of steps in accordance with the room temperature T _R with respect to the set temperature T _S. The relay unit 20, based a set temperature T _S, the room temperature T _R detected by radiation sensor 164, the floor heating mats 1
When the capacity limit level of 42 is set, an operation signal corresponding to the set capacity limit level is output to the control board 174 of the heat source unit 26.

Control board 17 of heat source unit 26
4, the thermal valve 76 based on the set limit level
Duty ratio for controlling on / off of the valve (thermal valve 76
On time).

In the present embodiment, as shown in Table 1, for example, the heating power limit levels are set to five levels from level 1 to level 5, and the temperature t ₁ ,
t ₂ and t ₃ are t ₁ <t ₂ <t ₃ and, for example, the temperature t
₁ = 1 ° C., temperature t ₂ = 2 ° C., temperature t ₃ = 3 ° C.

[0067]

[Table 1]

As shown in FIGS. 8 (B), 8 (C) and 8 (D), at level 2, level 3 and level 4, the on-time S ₀ of the thermal valve 76 is changed to the on-time, respectively. S
_1, by switching on time S ₂ and the on-time S _3,
70% output (heating capacity) by floor heating mat 142
At 50% and 30%, and at level 5, the thermal valve 76 is turned off to stop floor heating.

In the relay unit 20, the hot water air conditioner 10
To limit the heating capacity. That is, the hot water air conditioner 10 is set temperature T _S and the relay unit 20 controls the heating capacity on the basis of the room temperature T _R detected by radiation sensor 164, by performing the heating in conjunction with floor heating mat 142 In some cases, the room temperature may be higher than the set temperature. For this reason,
In the relay unit 20, a predetermined value or more with respect to the room temperature is a set temperature (e.g., temperature t ₂ or more, limit level is Level 4
In this case, the heating operation by the hot water air conditioner 10 is forcibly stopped.

That is, in the air conditioning system 10, when the hot water air conditioner 10 performs the heating operation in the automatic operation mode,
By performing the heating operation together with the floor heating mat 142, the heating capacity of the floor heating mat 142 and the heating by the hot water air conditioner 10 are controlled.

Next, the operation of the present embodiment will be described. In the air conditioning system 10, operating conditions such as an operation mode and a set temperature of the hot water air conditioner 10 are set by operating the system remote controller 130, and when an operation signal corresponding to the setting is transmitted, the operation signal is received by the relay unit 20. I do. The relay unit 20 separates the received operation signal into an operation signal to be sent to the indoor unit 22 of the hot water air conditioner 10 and an operation signal to be sent to the heat source unit 26 of the outdoor unit 14. The relay unit 20 sends the indoor temperature detected by the radiation sensor 164 to the indoor unit 22 together with the separated operation signal.

Here, when performing the cooling operation by the hot water air conditioner 10, the relay unit 20 transmits the radiation sensor 1 together with the received operation signal from the system remote controller 130.
The room temperature detected by the step 64 is sent to the indoor unit 22. The microcomputer 100 of the indoor unit 22 sets an operation mode, a set temperature, a flow rate, a wind direction, and the like based on the operation signal transmitted from the relay unit 20, and starts the air conditioning operation. At this time, the air-conditioning capacity is controlled based on the room temperature detected by the relay unit 20.

On the other hand, when the heating operation of the hot water air conditioner 10 is set by operating the switch of the system remote controller 130, the relay unit 20 outputs the operation signals necessary for controlling the indoor unit 22 from the operation signals of the system remote controller 130. The operation signal necessary for controlling the heat source unit 26 is separated, and the operation signal necessary for operating the indoor unit 26 is transmitted to the indoor unit 22 together with the indoor temperature.

On the other hand, an operation signal required for the heating operation using the heat source unit 26 is input from the relay unit 20 to the heat source unit 26. In addition, the heat source unit 26 changes the operation state at a predetermined timing to the relay unit 2.
Output to 0. The relay unit 20 includes a heat source unit 26
When a signal indicating the operation state of the heat source unit 26 is input from the controller, a signal corresponding to the input operation state of the heat source unit 26 is transmitted to the indoor unit 22.

Here, when the heat source unit 26 is set to the heating operation, the gas burner 70 is ignited, the pump 62 is operated, and the hot water heat exchanger 64 starts generating hot water. Is circulated with the radiator 18 of the indoor unit 22. Thereby, the conditioned air heated by passing through the radiator 18 from the outlet 52 of the indoor unit 22 is blown out. In the indoor unit 22, the opening degree of the variable flow rate valve 68 is set based on the set temperature, the indoor temperature, and the like, and the heating capacity is controlled by opening the variable flow rate valve 68 in the set step.

On the other hand, when the operation of the floor heating mat 142 is set by operating the system remote controller 130, the relay unit 20 transmits the operation signal received from the system remote controller 130 to the control board 174 of the heat source unit 26.
Send to As a result, the heat source unit 26 opens the thermal valve 76 to start supplying hot water to the floor heating mat 142.

At this time, the microcomputer in the control board 174 turns on / off (opens / closes) the thermal valve 76 at a preset duty ratio. Thereby, the surface of the mat 144 is warmed by the hot water circulated in the hot water tube 146 at predetermined time intervals.

In the air conditioning system 11 provided with the hot water air conditioner 10 and the floor heating mat 142, heating by the hot water air conditioner 10 and floor heating by the floor heating mat 142 are possible. In the air conditioning system 11, heating using either the hot water air conditioner 10 or the floor heating mat 142 can be performed by operating the system remote controller 130.

By the way, when the hot water air conditioner 10 is set to the automatic operation mode when the heating by the hot water air conditioner 10 and the heating of the floor heating mat 142 are performed at the same time, the air conditioning system 11 operates based on the set temperature and the indoor temperature. The operation of the hot water air conditioner 10 is controlled together with the heating capacity of the floor heating mat 142.

The operation control of the floor heating mat 142 and the hot water air conditioner 10 using the relay unit 20 will be described below. Note that the relay unit 20 is the radiation sensor 1
Reference numeral 64 describes an example in which the temperature on the floor heating mat 142 is detected as the room temperature. That is, the hot water air conditioner 10 performs the heating operation with the temperature of the floor heating mat 146 as the room temperature, and controls the floor heating capacity based on the temperature of the floor heating mat 146. At this time, the relay unit 20 can measure the room temperature (with an error within 1 ° C.) with relatively high accuracy by the radiation sensor 164.

FIG. 9 shows an example of the heating capacity control executed by the relay unit 20. This flowchart shows the heating operation of the hot water air conditioner 10 and the floor heating mat 142.
When the floor heating operation is set according to the first step 300
Is executed. In this step 300, it is confirmed whether or not the hot water air conditioner 10 is set to the automatic operation mode. If it is set to the automatic operation mode, an affirmative determination is made in this step 300 and the process proceeds to step 302. If the setting of the automatic operation mode of the hot water air conditioner 10 is released (set to the manual operation mode) or the operation of the hot water air conditioner 10 or the floor heating mat 142 is stopped, a negative determination is made in step 300. finish.

[0082] At step 302, reads the room temperature T _R which is detected by the radiation sensor 164 at a predetermined timing. After this, steps 304 to 310
Then, the set temperature T _S of the hot water air conditioner 10 set by the system remote controller 130 is compared with the room temperature T _R ,
Steps 312 to 32 based on the comparison result
0 sets the limit level of the heating capacity. Further, in step 322, the operation of the floor heating mat 142 and the hot water air conditioner 10 is controlled according to the set restriction level.

At this time, the heating capacity is controlled by outputting an operation signal corresponding to the set level from the relay unit 20 to the indoor unit 22 and the heat source unit 26, so that each of the indoor unit 22 and the heat source unit 26 It is driven according to the operation signal.

[0084] At step 304, checks whether the room temperature T _R has reached the set temperature T _S, unless the room temperature T _R reaches the set temperature _{T S (T R <T S} ), a step 304 Is affirmatively determined, and the routine goes to step 312. In this step 312, the limit level of the heating capacity is set to level 1. As shown in Table 1, Level 1
Then, since the hot water air conditioner 10 as well as the floor heating mat 142 is set to the normal control, the heat source unit 26
The hot valve 76 is controlled at a normal duty ratio (see FIG. 8A) to supply hot water at a predetermined temperature into the hot water tube 146 intermittently. As a result, the room is warmed by the indoor unit 22 of the hot water air conditioner 10 and the floor heating mat 142 to the set temperature T _S.

On the other hand, the room temperature TR is _equal to the set temperature T.
_{When S} has been reached, a negative determination is made in step 304 and the routine proceeds to step 306.

[0086] In step 306, checks whether the room temperature T _R is over the temperature t ₁ than the set temperature T _S.
When the temperature difference between the set temperature T _S of the room temperature T _R which exceeds the set temperature T _S is within the temperature _{t 1 (T S ≦ T R} <T S + t
_{In 1} ), an affirmative determination is made in step 306, and the process proceeds to step 314.

At step 314, the heating power limit level is set to level 2. Thereby, the hot water air conditioner 10 continues the normal control, but the heat source unit 26
The heating capacity of the floor heating unit 142 is limited to 70%.
As shown in FIG. 8B, the limitation of the heating capacity
Changing the Deyute ratio by limiting the time that is on the Netsudoben 76 to on-time S _1. As a result, the amount of heat supplied to the floor heating mat 142 is reduced by reducing the time during which the thermal valve 76 is on, and the heating capacity of the floor heating mat 142 is reduced.

On the other hand, the heating capacity of the floor heating mat 142 is affected by the environment. For example, when the outside air temperature is relatively high, the surface temperature of the mat 144 gradually increases even if the heating capacity is limited. As a result, the room temperature T _R
Also rises. Thus, the room temperature T _R is the set temperature T
When the temperature difference between the _S exceeds the temperature t ₁ is determined to be negative in step 306, the routine proceeds to step 308. In step 306, the temperature difference between the room temperature T _R and the set temperature T _S to check whether exceeds the temperature t _2.

[0089] In step 308, checks whether the room temperature T _R is over the temperature t ₂ than the set temperature T _S.
The _{(T S + t 1 ≦ T} R <T S + t 2) when the temperature difference between the set temperature T _S of the set temperature T indoor temperature exceeds _S T _R was within a temperature t ₂ at the temperature t ₁ or more , Step 30
The determination at step 8 is affirmative, and the process proceeds to step 316.

In step 316, the heating capacity level is set to level 3. The heat source unit 26 further reduces the duty ratio when the thermal valve 76 is turned on / off so that the heating capacity of the floor heating mat 142 is further reduced by setting the heating capacity limit level to level 3. At the level 3, the heating capacity of the floor heating mat 142 is limited to 50%, and as shown in FIG. 8C, the on-time of the thermal valve 76 is set to the on-time S ₁ at the level 2. and short on time S ₂ than.

As a result, the amount of heat supplied from the heat source unit 26 to the floor heating mat 142 is further suppressed, and the heating capacity of the floor heating mat 142 is reduced to about 50% of the normal state.
Can be lowered further.

In the hot water air conditioner 10, the room temperature T
_{Since the} heating operation is performed so that _R becomes the set temperature T _S , the relay unit 20 sets the heating capacity limit level to level 3
So it does not limit the heating capacity of the hot water air conditioner 10, the hot water air conditioning 10, by the room temperature T _R exceeds the set temperature T _S, operated by suppressing heating capacity.

Thus, when the relay unit 20 is set to level 3, the indoor heating capacity is greatly reduced.

On the other hand, if the temperature difference between the room temperature T _R and the set temperature T _S exceeds the temperature t ₂ , a negative determination is made in step 308 and the routine proceeds to step 310. This step 310
So the temperature difference between the room temperature T _R the set temperature T _S exceeding the temperature t ₂ has to check exceeds the temperature t _3.

[0095] Here, when the temperature difference between the room temperature T _R and the set temperature T _S does not exceed the temperature t _3, the step 31
If the determination is affirmative, the process proceeds to step 318 to set the limit level of the heating capacity to level 4. The temperature difference between the room temperature T _R and the set temperature T _S is when exceeding the temperature t ₃ is a negative decision is made at step 310 is set to level 5 limits the level of heating capacity and proceeds to step 320.

In the heat source unit 26, the floor heating mat 14
By limiting the level of the second heating capacity is set to level 4, as shown in FIG. 8 (D), the on-time shorter time S ₃ of Netsudoben 76. As a result, the duty ratio when operating the thermal valve 76 further decreases, and the amount of heat supplied to the floor heating mat 142 further decreases (limited to about 30%).

In the heat source unit 26, the heating valve 76 is closed by setting the heating capacity limit level of the floor heating mat 142 to level 5, thereby closing the floor heating mat 1
The supply of warm water to 42 is stopped.

On the other hand, in the hot water air conditioner 10, the indoor temperature T
_{When R} rises significantly above the set temperature T _S and the heating capacity limit level exceeds level 4, the heating operation is stopped.

Therefore, in the air-conditioning system 10, by setting the limit level of the heating capacity to level 4,
Heating capacity to perform heating only floor heating mats 142 extremely low, which even when the room temperature T _R is increased not only heating by the hot water air conditioner 10, the heating is also stopped by the floor heating mat 142, the indoor temperature T _This prevents _R from exceeding the set temperature T _S more than necessary.

[0100] Thus, in the air conditioning system 11, when subjected to heating at the same time by the hot water air conditioner 10 and the floor heating mat 142 lowers stepwise heating capacity in accordance with the increase of the room temperature T _R.

As a result, as shown in FIG.
Detected by the radiation sensor 164 of the relay unit 20
Surface temperature of the floor heating mat 142 (room temperature T_R)
Set temperature T_SThe degree of temperature rise
Set temperature T _SIs the temperature t_ThreeTo
If it exceeds, the heating operation stops, so the room temperature T_RIs set
Constant temperature T_SCan be prevented from exceeding significantly.

That is, as shown by the two-dot chain line in FIG. 10, in the conventional floor heating mat, T _s (set temperature) + t ₂
(E.g., 2 ° C.) to the thermo-off as overshoot treated, so as to thermo when a T _s or T _s + t _1. For this reason, when heating is performed using a floor heating mat and another heating device such as the hot water air conditioner 10, the room temperature becomes unstable. In contrast, because it is also combined with the control operation of the hot-water air conditioner 10 with the heating capacity of the floor heating mat 142, it is possible to stabilize the room temperature T _R.

In addition to the hot water air conditioner 10, the floor heating
Set the heating capacity of the heater 142 to the set temperature T. _SRestrict according to
Therefore, by heating with an unnecessarily large heating capacity,
Energy consumption and energy saving.
It is planned.

In the present embodiment, the hot water air conditioner 1
The temperature sensor 126 provided in the indoor unit 22 detects the indoor temperature used when the 0 controls the heating capacity. The relay unit 20 detects the indoor temperature when the hot water air conditioner 10 controls the air conditioning capacity. it may be using the room temperature T _R. Also in this case, on the basis of the room temperature T _R detected by the relay unit 20 may be collectively limit the heating due to heating and floor heating mat 142 by hot air conditioner 10.

In the present embodiment, the floor heating mat 1
The temperature on the 42 and the indoor temperature T _R, but the relay unit 2
Room temperature T _R to detect the 0 may be detecting the temperature of any area to be the set temperature during the heating, thereby efficiently as region temperature detected by the relay unit 20 becomes the set temperature T _S Heating can be performed.

In the present embodiment described above, the configuration of the present invention is not limited. In the present embodiment, an air conditioner and a hot water air conditioner 1 using hot water for heating are used.
Although described using 0, the present invention can use a general air conditioner that performs heating operation together with cooling using a refrigeration cycle in which a refrigerant circulates.

Further, in this embodiment, the floor heating unit uses the hot water type floor heating mat 142 for heating with the hot water generated by the heat source unit 26, but the floor heating unit uses an electric heater for heating. A floor heating carpet or the like can be used. In this case, the relay unit 20 may limit the heating capacity (for example, power consumption) of the electric floor heating carpet or the like.

Thus, conventionally, the air conditioner and the floor heating unit individually perform the heating capacity control collectively, so that efficient heating and energy saving can be achieved.

In this embodiment, the floor heating mat 1
Although the relay unit 20 is provided separately from the indoor unit 22 of the hot water air conditioner 10, the relay unit 20 may be built in the indoor unit 12 together with the indoor unit 22. Also, the function of the relay unit 20 is also provided to the indoor unit 20 of the hot water air conditioner 10,
The indoor unit 22 may limit the heating capacity of the floor heating mat 142 together with the heating capacity of the hot water air conditioner 10.

[0110]

As described above, according to the present invention, when performing the heating operation using the air conditioner and the floor heating device together, the set temperature and the room temperature set as the operating conditions of the air conditioner are reduced. Accordingly, the heating capacity of not only the air conditioner but also the floor heating device is limited, so that the room temperature can be prevented from greatly exceeding the set temperature. An excellent effect that energy can be saved can be obtained.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram showing a hot water air conditioner applied to the present embodiment.

FIG. 2 is a schematic diagram showing an arrangement of an indoor unit, a relay unit, and a floor heating mat of the hot water air conditioner.

FIG. 3 is a schematic system diagram showing a flow path of a refrigerant and hot water of the hot water air conditioner applied to the present embodiment.

FIG. 4 is a schematic diagram showing a board configuration of an electric circuit of the indoor unit.

FIG. 5 is a schematic diagram showing a substrate configuration of an electric circuit of the heat source unit.

FIG. 6 is a schematic configuration diagram showing a relay unit applied to the present embodiment.

FIG. 7 is a diagram illustrating an example of a change in room temperature when heating a room with a hot water air conditioner;

FIG. 8 is a diagram showing an example of on / off control of a thermal valve during heating by a floor heating device, where (A) is level 1 for normal operation, (B) is level 2 and (C) is level. Level 3, (D)
Indicates level 4, respectively.

FIG. 9 is a flowchart showing an outline of heating capacity control by the relay unit.

10 is a diagram showing an example of a temporal change of the room temperature (the surface temperature of the floor heating mat) when heating capacity control is performed with the temperature on the floor heating mat as the room temperature based on the flowchart shown in FIG. 9; is there.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Hot water air conditioner (air conditioner) 11 Air conditioning system (heating system) 12 Indoor unit 14 Outdoor unit 16 Evaporator 18 Radiator 20 Relay unit (Temperature detection means, Limiting means) 22 Indoor unit 24 Refrigerant unit 26 Heat source unit (Air conditioning) , Floor heating device) 130 system remote control 142 floor heating mat (floor heating device) 152 control board (limitation means) 158 temperature detection board (temperature detection means) 164 radiation sensor (temperature detection means) 174 control board

Claims (5)

[Claims] 1. An air conditioner for heating an indoor room to a set temperature by blowing air controlled by a heat exchanger provided in the indoor unit from the indoor unit, and a floor heater laid on the indoor floor surface. A floor heating device that heats the room from the floor by a unit; a temperature detection unit that detects a temperature of the room heated by the air conditioner and the floor heating device; a set temperature of the air conditioner and the temperature detection. Heating means for limiting at least the heating capacity of the floor heating device based on the room temperature detected by the means. 2. The heating system according to claim 1, wherein the operation is performed when the restricting unit is set to an automatic operation as an operation condition of the air conditioner. 3. The method according to claim 1, wherein said limiting means limits the heating capacity of said floor heating device in a plurality of stages according to a temperature difference between said room temperature and said set temperature. The heating system according to any one of the above. 4. The heating system according to claim 1, wherein said temperature detecting means detects a temperature near a floor surface heated by said floor heating device. 5. The heating device according to claim 5, wherein the limiting unit stops heating operations of the floor heating device and the air conditioner when the room temperature becomes higher than the set temperature by a predetermined value or more during the heating operation. The heating system according to any one of claims 1 to 4, characterized in that: