KR960002084Y1 - Airconditioner - Google Patents

Abstract

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Description

Air conditioner

1 is a circuit diagram of a heating and cooling device showing an embodiment according to the first invention

2 is a block diagram showing the basic control overview according to the first design.

2 (b) is a flowchart for explaining the basic control outline according to the first design.

3 is a fuzzy rule diagram for estimating the amount of change in the set temperature according to the first design.

4 is a characteristic diagram showing the inference result of the change amount of the set temperature according to the first design

5 is a circuit diagram of a heating and cooling device showing an embodiment according to the second invention

6 is a block diagram showing the basic control overview according to the second invention.

7 is a fuzzy rule diagram for inferring the change amount of the set temperature by the second design.

8 is a characteristic diagram showing the inference result of the change amount of the set temperature by the second design

9 is a circuit configuration diagram of an air conditioner and an air heater according to one embodiment of the third invention.

10 is a block diagram showing the basic control overview according to the third design

11 is a fuzzy rule diagram for inferring the change amount of the set temperature according to the third design.

12 is a characteristic diagram showing the inference result of the change amount of the set temperature according to the third design

13 is a circuit diagram of a heating and cooling device showing an embodiment according to the fourth invention

14 is a block diagram showing the basic control overview according to the fourth invention.

FIG. 15 is a fuzzy rule diagram for inferring the change amount of the set temperature according to the fourth design.

Figure 16 is a characteristic diagram showing the result of inferring the amount of change in the set temperature according to the fourth design

17 is a circuit diagram of a heating and cooling device showing an embodiment according to the fifth invention

18 is a block diagram showing the basic control overview according to the fifth design.

19 is a fuzzy rule diagram for inferring the change amount of the set temperature according to the fifth design.

20 is a characteristic diagram showing the result of inferring the change amount of the set temperature according to the fifth design

21 is a circuit diagram of a heating and cooling device showing an embodiment according to the sixth invention

22 is a block diagram showing the basic control overview according to the sixth invention.

23 is a fuzzy rule diagram for inferring the change amount of the set temperature according to the sixth invention.

24 is a characteristic diagram showing the inference result of the change amount of the set temperature according to the sixth invention

25 is a circuit diagram of a conventional air conditioner

26 is a block diagram of a sensory input unit of a conventional air conditioner

27 is a characteristic curve showing a change amount of a set temperature of a conventional air conditioner

28 is a flowchart showing an algorithm of changing a set temperature of a conventional air conditioner.

* Explanation of symbols for main parts of the drawings

6 sense input unit 13 room temperature detector

14: bottom temperature detector 15: set temperature changing means

19: floor temperature detector 22: wall temperature detector

25: radiation temperature detector 28: second room temperature detector

29: heating and cooling capacity detector

The present invention relates to a change in the set temperature of the air conditioning unit used in homes or offices.

FIG. 25 is an electrical circuit diagram of a conventional air-conditioning apparatus shown in, for example, Japanese Patent Laid-Open No. 63 (1988) -14028. In this figure, reference numeral 1 denotes an operation switch, reference numeral 2 denotes a temperature detector for detecting an indoor temperature of a room to be cooled and heated, reference numeral 3 denotes an A / D converter for converting a value of the temperature detector 2 into a digital value, (6) is a switch section having a plurality of sense switches for changing the set temperature in accordance with the user's senses, (7) is a microcomputer having a means for changing the set temperature, the input circuit (8), cpu (9) And a memory 10 and an output circuit 11. Denoted at 12 is a compressor controlled by a signal from the output circuit 11.

FIG. 26 shows the structure of the switch part 6, and the switch part 6 is provided with a sensor switch 6a for operating when it feels hot, a sensor switch 6b for operating when it feels cold, and the like.

The microcomputer 7 has determination means for determining the set temperature from the information of the sense switch 6 and the temperature detectors 2 and 3, and the memory 10 has a room temperature as shown in FIG. ) Change data of the set temperature is stored.

Next, the operation will be described in accordance with the flowchart of FIG. This flowchart is a part of the program for changing the set temperature stored in the memory 10 of the microcomputer 7 in FIG. 25, and the case of heating operation will be described here.

When the operation switch 1 of FIG. 25 is turned on, the operation of the flowchart of FIG. 28 is started, and in step 101, the initial setting is set.

Subsequently, the indoor temperature is detected by the temperature detectors 2 and 3 at step 102, the detection signal is input to the microcomputer 7, and the set temperature and the indoor temperature are compared at step 103.

The control signal is output from the output circuit 11 in accordance with the operation mode, and the compressor 12 is turned on and off in steps 104 and 105. In the following steps 106 to 113, a flowchart of the set temperature change is shown. If it is determined in step 107 that there is an input from the sense switch 6, the input of the switch 6a when it is hot in step 107 or when it is cold. It is determined whether the switch 6b is input. When it is determined that the input from the switch 6a at the time of step 107 is hot, the change width of the set temperature is determined from the characteristic curve A of the change width of the room temperature set temperature shown in FIG. Change the set temperature. This room temperature change width in FIG. 27 is small when the room temperature is lower than the predetermined value when the signal from the sensor switch 6a when hot is input, and becomes larger when the room temperature is higher than the predetermined value.

If it is judged that the input is from the switch 6b when cold in step 107, the change width of the set temperature is determined from the characteristic curve B of the room temperature change width shown in FIG. 27 in step 111, and is set in step 113. Change the temperature.

Here, as shown in FIG. 27, the room temperature change width when the signal from the sensor switch 6b during cold is input is large when the room temperature is lower than the predetermined value and becomes small when the room temperature is higher than the predetermined value. have.

Subsequently, the operation from step 102 is performed again at the set temperature changed as described above, and the compressor 12 is turned on and off so that the set temperature is equal to the room temperature, and the environment is comfortably controlled.

In this way, the room temperature is controlled according to the user's senses.

The air conditioner is used to maintain the indoor environment in a comfortable environment. Temperature is the main controllable element of air conditioners. The thermal sensation, such as hot or cold, is determined by the balance between the amount of heat released from the human body and the amount of heat produced by the human body. The amount of heat dissipation from the human body is determined by temperature, humidity, radiation, and airflow, which are four elements of heat, and the heat sensation is determined by these. The air conditioner controls the temperature of the four elements of heat, creating a pleasant environment.

In addition, the thermosensory receptors, which are large in size and feel hot and cold, are distributed throughout the skin. The thermosensory of the human body is determined as the aggregate result of the thermosensory receptors spread throughout the skin. Therefore, when determining the set temperature according to the user's sensory input, it is necessary to consider not only the temperature but also the distribution of the four thermal elements and the four thermal elements. However, in the air conditioner as described above, even if each of the sensor switches 6a and 6b is operated when it is hot or when it feels cold, the set temperature is only changed in accordance with the room temperature at that time. There was a problem that the distribution of the four elements of heat was not taken into account and did not match the human sense.

This invention is made | formed by solving such a subject, and an object of this invention is to provide the comfortable air-conditioning apparatus which determines the setting temperature according to a user's sense.

The air conditioning and heating device according to the first invention includes a sensory input unit for inputting a user's thermal sensation, a room temperature detector mounted on the air conditioner and a representative value of the room temperature, and mounted near the floor than the room temperature detector. By the output of the bottom air temperature detector for sensing the temperature near the bottom, and the output of the sensor input unit, the room temperature detector and the temperature detector, the set temperature is lowered during sensory input indicating a hot situation, and during sensory input indicating cold situation. Has a set temperature determining means for changing the set temperature high and a set temperature changing width determining means for changing the changing range of the set temperature by the room temperature and the temperature measured by the temperature detector.

The air conditioning and heating device according to the second invention is the floor temperature detector for detecting the temperature of the floor, the temperature detector being mounted on the floor according to the first invention.

In the third invention, the air conditioner is a wall temperature detector that is mounted on a wall and detects a wall temperature.

According to a first aspect of the present invention, the air conditioner is a radiation temperature detector that is mounted on the air conditioner and detects an indoor radiation temperature.

In a fifth aspect of the present invention, the air conditioner is a second room temperature detector that detects a temperature near the remote control unit by detaching the air conditioner from the air conditioner and attaching the remote control unit to operate the air conditioner.

In a sixth aspect of the present invention, the air conditioner is composed of air-conditioning and control means for controlling the air-conditioning capacity so that the indoor temperature is equal to the set temperature.

In this first design, the heating and cooling equipment uses information on the air temperature near the floor that has a great influence on the user's thermal sensation as information, not just the room temperature, when the user inputs the sensory input. When both the room temperature and the near-air temperature are low, raise the set temperature significantly.When the room temperature or only the bottom near-air temperature is low, raise the set temperature slightly. The user's senses are inferred by the room temperature and the air temperature near the floor, such as lowering the set temperature significantly when both sides of the bottom air temperature are high and slightly lowering the temperature when only the indoor temperature or only the floor air temperature is high. The set temperature is controlled in accordance with the user's preference.

In this second design, the heating and cooling device uses information on the floor temperature that has a great influence on the user's thermal sensation, as well as the room temperature, when the user inputs the sensory input. When both the room temperature and the floor temperature are low, raise the set temperature significantly.When the room temperature or only the floor temperature is low, raise the set temperature slightly.When it is hot, when the temperature is high, when both the room temperature and the floor temperature are high, It is to infer user's sensibility by indoor temperature and floor temperature and to control the set temperature according to user's preference, such as lowering the set temperature significantly and lowering the set temperature slightly when only the indoor temperature or only the floor temperature is high. .

The air conditioning and heating device in this third design uses information of not only the room temperature but also the wall temperature which has a great influence on the user's thermal sensation at the time of user's sensory input. If both the room and wall temperature are low, increase the set temperature. If the temperature is only indoor or only the wall temperature is low, raise the set temperature a little. If it is hot, input is greatly increased when both the room and wall temperature are high. When the set temperature is lowered and only the indoor temperature or only the wall temperature is high, the user's senses are inferred by the room temperature and the wall temperature, and the set temperature is controlled according to the user's preferences. .

The air conditioner according to the fourth aspect of the present invention uses not only the room temperature but also the radiation temperature of the room which greatly affects the user's thermal sensation at the time of user's sensory input. If the temperature of both room and radiation is low, increase the set temperature. If the temperature is only low or room temperature, increase the set temperature. If the temperature is high, set the temperature higher if both the room and radiation temperature are high. When the temperature is lowered and the temperature of only the indoor temperature or only the radiation temperature is high, the user's senses are inferred by the room temperature and the radiation temperature and the set temperature is controlled according to the user's preferences, such as lowering the set temperature slightly.

In the fifth aspect of the invention, the heating and cooling device is located at a temperature near the remote control unit that controls not only the room temperature (the first room temperature) but also the air conditioner that greatly affects the user's thermal sensation. Indoor temperature), and, for example, when it is cold, when the temperature of both the first room temperature and the second room temperature is low, the set temperature is greatly increased, and only the first room temperature or the second room temperature is increased. When the indoor temperature alone is low, increase the set temperature slightly, and when it is hot, when the temperature is high, decrease the set temperature significantly when both the first indoor temperature and the second indoor temperature are high, and only the first indoor temperature or When the temperature of only the room temperature of 2 is high, the user's sense is inferred by the first room temperature and the second room temperature, and the set temperature is controlled according to the user's preference, such as lowering the selected temperature slightly.

In the sixth aspect of the present invention, the air conditioning system infers not only the room temperature at the user's sensory input, but also the radiation temperature which has a great influence on the user's sense of heat from the air conditioner's cooling and heating capacity. For example, if the air conditioner's cooling / heating capacity is used as information, for example, when the input is cold, when the room temperature is low and the cooling / heating capacity of the air-conditioning device is large, increase the set temperature significantly. Increase the set temperature a little bit when it's hot, and lower the set temperature when the temperature is high when the input is hot, decrease the set temperature when the air conditioner's temperature is high or when the air conditioner's temperature is low. Inference of the user's senses from the room temperature and the cooling and heating capacity of air conditioning equipment and controlling the set temperature according to the user's preference The.

Next, an embodiment of the present invention will be described with reference to the drawings.

1 to 4 show an embodiment of the first invention, FIG. 1 is a circuit configuration diagram, in which: (1) represents an operation switch and (2) detects an indoor temperature of a room to be heated and cooled. The room temperature detection element (3) is an A / D converter for converting the value of the room temperature detection element (2) into a digital value, and (4) is mounted near the bottom than the room temperature detection element (2). Near air temperature detecting element for detecting the temperature of (5), A / D converter for converting the value of the near air temperature detecting element (4) to digital value, (6) change the set temperature according to the user's sense (7) is a microcomputer with a means for changing the set temperature, and has an input circuit (8), a CPU (9), a memory (10), and an output circuit (11). have. Denoted at 12 is a compressor controlled by a signal from the output circuit 11.

The switch part 6 is provided with the sensor switch 6a which operates when it feels hot, and the sensor switch 6b which operates when it feels cold.

Fig. 2 (a) is a block diagram showing the basic control outline. In the drawing, reference numeral 13 denotes a room temperature detector, reference numeral 14 denotes a temperature detector near the bottom, and reference numeral 15 denotes a set temperature change width determining means. The change amount of the set temperature is determined from the room temperature detector 13 and the near-side temperature detector 14 when the input signal from the switch 6 and the sensory input switch 6 are pressed. Reference numeral 16 denotes a set temperature determining means, which subtracts when the change width of the set temperature determined by the set temperature change width determining means 15 is hot, based on the room temperature detector 13 when the sense input switch is pressed. In case of cold, set temperature is added. The set temperature change width determining means 15 and the set temperature determining means 16 are constituted by, for example, a microcomputer 7.

Next, the operation will be described in accordance with the flowchart of FIG. 2 (b) in which the block diagram showing the basic control outline of FIG. This flowchart is part of a program of setting temperature change stored in the memory 10 of the microcomputer 7 of FIG. Here, the case of heating operation is demonstrated.

When the operation switch 1 of FIG. 1 is turned on, the operation of the flowchart of FIG. 2B is started, and the initial set temperature is first calculated in step 201. Next, the room temperature is detected by the room temperature detector 13 in step 202, the detection signal is input to the microcomputer 7, and the heating capacity is controlled from the set temperature and the room temperature in step 203. If it is judged that there is an input from the sensory input switch unit 6 in step 204, the air temperature near the bottom is detected by the bottom temperature detector 14 in step 205, and the switch 6a when it is hot in step 206 is performed. It is determined whether or not the input of the switch or the input of the switch 6b is cold.

If it is determined in step 206 that the input from the switch 6a is hot, then in step 207 a fuzzy rule is applied to determine the change in the set temperature from the room temperature and the near-air temperature. Change the set temperature at. If it is judged that the input from the switch 6b is cold at the stem 206, the purge is applied in step 208 to determine the change in the set temperature from the room temperature and the near air temperature, and the set temperature is changed in step 210. do. Then, the operation from step 202 is performed again from the set temperature changed as described above, so that the room temperature is controlled in accordance with the user's sense.

3 is a fuzzy rule diagram for inferring a change amount of a set temperature. For example, when the sensor switch 6a in the hot state is pressed and the room temperature is high and the air temperature near the floor is high from the detected room temperature and the near-floor temperature, the amount of change to lower the set temperature is set to (larger). When the room temperature is low and the air temperature near the floor is low, the change amount to lower the set temperature is set to (small), and when the room temperature is high, the air temperature near the floor is low, or when the room temperature is low and the air temperature near the floor is high. The change amount to lower the set temperature is set to (normal). Although not shown, when the sensory switch 6b in cold is pressed, the amount of change to raise the set temperature when the room temperature is high and the air temperature near the floor is high from the detected room temperature and the near-floor temperature ( Small), and when the room temperature is low and the air temperature near the floor is low, the change amount to raise the set temperature is (large), and when the room temperature is high and the air temperature near the floor is low or the room temperature is low and the air temperature near the floor is low. When is high, the change amount to raise the set temperature is set to (normal). This fuzzy inference is performed by a program stored in the memory 10 of the microcomputer 7.

4 is a characteristic diagram showing an inference result of the amount of change in the set temperature performed by the set temperature change width determining means 15 of the microcomputer 7. As shown in the figure, the membership function when the room temperature is 21 [° C.] is normal (expansion is 1.0). Again, the membership function is usually (= 1.0) when the floor near-temperature is 21 [℃]. At this time, by applying the fuzzy rule, the set temperature range is 2 [deg], and the new set temperature is 21-2 = 19 [° C]. Similarly, the change in the set temperature when the near-floor temperature is 23 [° C.] is 2.75 [deg], and the new set temperature is 18.25 [° C.]. In this way, even at the same room temperature, the change range of the set temperature is changed by the air temperature near the floor, whereby the set temperature close to the human sense can be changed.

Next, an embodiment of the second invention will be described with reference to the drawings. 5 to 8 show an embodiment of the second invention, FIG. 5 is a circuit configuration diagram, in which: (1) indicates an operation switch and (2) detects an indoor temperature of a room to be heated and cooled. The room temperature detection element (3) is an A / D converter for converting the value of the room temperature detection element (2) into a digital value, and (17) is mounted near the bottom than the room temperature detection element (2) to detect the temperature of the floor. The bottom temperature detecting element (18) is an A / D converter for converting the value of the bottom temperature detecting element (17) into a digital value, and (6) a switch having a plurality of sense switches for changing the set temperature according to the user's sense. (7) is a microcomputer having a means for changing the set temperature, and has an input circuit 8, a CPU 9, a memory 10, and an output circuit 11; Denoted at 12 is a compressor controlled by a signal from the output circuit 11.

The switch part 6 is provided with the sensor switch 6a which operates when it feels hot, the sensor switch 6b which operates when it feels cold.

FIG. 6 is a block diagram showing the basic control outline, where reference numeral 13 denotes a room temperature detector, reference numeral 19 denotes a floor temperature detector, reference numeral 15 denotes a set temperature change width determining means, and The amount of change in the set temperature is determined from the room temperature detector 13 and the bottom temperature detector 19 when the input signal and the sensory input switch 6 are pressed. Reference numeral 16 denotes a set temperature determining means, which subtracts when the change width of the set temperature determined by the set temperature change width determining means 15 is hot, based on the room temperature detector 13 when the sense input switch is pressed. In case of cold, the set temperature is determined. The set temperature change width determining means 15 and the set temperature determining means 16 are constituted by, for example, a microcomputer 7.

Then, in the flowchart of FIG. 2 (b) showing the operation of the first design, if the "bottom air temperature detection" of step 205 is "floor temperature detection", the operation of the second design is otherwise. Since the steps are the same, the description is omitted.

7 is a fuzzy rule diagram for inferring a change amount of a set temperature. For example, from the detected room temperature and the floor surface temperature when the sensor switch 6a when hot is pressed, when the indoor temperature is high and the floor temperature is high, the change amount for lowering the set temperature is set to (large). When the room temperature is low and the floor temperature is low, the change amount for lowering the set temperature is set to (small), and when the room temperature is high and the floor temperature is low, or when the room temperature is low and the floor temperature is high, the set temperature is decreased. Set the change amount to (normal). Although not shown, from the detected room temperature and the floor surface temperature when the sensory switch 6b during cold is pressed, when the room temperature is high and the floor temperature is high, the change amount for raising the set temperature (small When the room temperature is low and the floor temperature is low, the change amount to raise the set temperature is (large), and when the room temperature is high and the floor temperature is low, or when the room temperature is low and the floor temperature is high. Set the change amount that raises the set temperature to (normal). This fuzzy inference is performed by a program stored in the memory 10 of the microcomputer 7.

8 is a characteristic diagram showing an inference result of the amount of change in the set temperature performed by the set temperature change width determining means 15 of the microcomputer 7. As shown in the figure, the membership function when the room temperature is 21 [° C.] is usually (expansion 1.0), and the member room function when the floor temperature is 21 [° C.] is usually (= 1.0). At this time, by applying the fuzzy rule, the set temperature range is 2 [deg]. The new set temperature is 21-2 = 19 [° C]. Similarly, when the floor temperature is 23 [° C], the change in the set temperature is 2.75 [deg], and the new set temperature is 18.25 [° C]. In this manner, even at the same room temperature, the change range of the set temperature changes in accordance with the floor surface temperature, whereby the set temperature close to the human sense can be changed.

9 to 12 show an embodiment of the third invention, FIG. 9 is a circuit configuration diagram of an air conditioner, and in the drawing, reference numeral 1 denotes an operation switch. (2) is a room temperature detector for detecting the room temperature of the room to be cooled and heated, (3) an A / C converter for converting the value of the room temperature detector (2) to a digital value, (20) is used to detect the temperature of the wall of the room where the air conditioner is installed The wall temperature detecting device 21 is an A / D converter for converting the value of the wall temperature detecting device 20 into a digital value, and the sensor 6 has a plurality of sensory switches for changing the set temperature according to the user's sense. The switch section 7 is a microcomputer having a means for changing the set temperature, and has an input circuit 8, a CPU 9, a memory 10, and an output circuit 11. Denoted at 12 is a compressor controlled by a signal from the output circuit 11.

The switch part 6 is provided with the sensor switch 6a which operates when it feels hot, and the sensor switch 6b which operates when it feels cold.

FIG. 10 is a block diagram showing the basic control outline, where reference numeral 13 denotes a room temperature detector, reference numeral 22 denotes a wall temperature detector, reference numeral 15 denotes a change width determining means of a set temperature, and a sensory input switch 6 The amount of change in the set temperature is determined from the room temperature detector 13 and the wall temperature detector 22 when the input signal from the sensor and the sensory input switch 6 are pressed. Reference numeral 16 denotes a set temperature determining means, which is based on the room temperature detector 13 when the sensory input switch is pressed, subtracting the change width determined by the set temperature change width determining means 15 when it is hot, and when it is cold. In addition, the set temperature is determined. The set temperature change width determining means 15 and the set temperature determining means 16 are constituted by, for example, a microcomputer 7.

In the flowchart of FIG. 2 (b) showing the operation of the first design, if the "bottom air temperature detection" of step 205 is "wall temperature detection", the operation of the third design is otherwise. Since the steps are the same, the description is omitted.

11 is a fuzzy rule diagram for inferring a change amount of a set temperature. For example, when the indoor temperature is high and the wall temperature is high from the room temperature and the wall temperature detected when the sensor switch 6a when hot is pressed, the change amount for lowering the set temperature is set to (large), and the room temperature. Is low and the wall temperature is low. The change amount that lowers the set temperature is set to (small), and when the room temperature is high and the wall temperature is low, or when the room temperature is low and the wall temperature is high, the change amount that lowers the set temperature is set to (normal). Although not shown, when the sensory switch 6b in cold is pressed, when the indoor temperature is high and the wall temperature is high from the detected room temperature and wall temperature, the change amount for raising the set temperature is set to (small). When the room temperature is low and the wall temperature is low, the change amount to raise the set temperature is set to (large), and the change amount to raise the set temperature when the room temperature is high and the wall temperature is low, or when the room temperature is low and the wall temperature is high. Let (usually) be.

This fuzzy inference is performed by a program stored in the memory 10 of the microcomputer 7.

12 is a characteristic diagram showing an inference result of the amount of change in the set temperature performed by the set temperature change width determining means 15 of the microcomputer 7. As shown in the figure, the membership function when the room temperature is 21 [° C.] is normal (expansion is 1.0). Again, when the wall temperature is 21 [℃], the membership function is usually (1.0). At this time, by applying the purge roll, the set temperature range is 2 [deg], and the new set temperature is 21-2 = 19 [° C]. Similarly, when the wall temperature is 15 [° C.], the change range of the set temperature is 1.25 [deg], and the new set temperature is 19.75 [° C.]. In this manner, even at the same room temperature, the width of change of the set temperature is changed by the wall temperature, whereby the set temperature close to the human sense can be changed.

13 to 16 show an embodiment of the fourth invention, and FIG. 13 is a circuit diagram of a heating and cooling device. In the drawing, reference numeral 1 denotes an operation switch and reference numeral 2 denotes an indoor temperature of a room to be heated and cooled. Room temperature detection element for detecting a (3), an A / D converter for converting the value of the room temperature detection element (2) to a digital value, (23) a radiation detection element for detecting a radiation temperature in a room where an air conditioner is installed, (24) Is an A / D converter for converting the value of the radiation detecting element 23 into a digital value, (6) is a switch unit having a plurality of sensor switches for changing the set temperature in accordance with the user's senses, (7) is the set temperature It is a microcomputer with a means for changing the circuit, and has an input circuit (8), a CPU (9), a memory (10), and an output circuit (11). Denoted at 12 is a compressor controlled by a signal from the output circuit 11. In the switch section (6). Sensor switch 6a to operate when it feels hot. Sensor switch 6b etc. which operate when it feels cold are arrange | positioned.

FIG. 14 is a block diagram showing the basic control outline, in which, (13) is a room temperature detector and (25) is a radiation detector. Denoted at 15 is a set temperature change width determining means, which changes the set temperature from the room temperature detector 13 and the radiation detector 25 when the input signal from the sensory input switch 6 and the sensory input switch 6 are pressed. Determine the amount. Reference numeral 16 denotes a set temperature determining means, which is based on the room temperature detector 13 when the sense input switch is pressed, subtracting the change width determined by the set temperature change width determining means 15 when it is hot, and when it is cold. In addition, determine the set temperature. The set temperature change width determining means 15 and the set temperature determining means 16 are constituted by, for example, a microcomputer 7.

In the flowchart of FIG. 2 (b) showing the operation of the first design, if the "bottom air temperature detection" of step 205 is "radiation temperature detection", the operation of the fourth design is otherwise. Since the steps are the same, the description is omitted.

15 is a fuzzy rule diagram for inferring a change amount of a set temperature. For example, from the room temperature and the radiation temperature detected when the sensor switch 6a when hot is pressed, when the room temperature is high and the radiation temperature is high, the change amount for lowering the set temperature (large) is set to (room temperature). When the temperature is low and the copy temperature is low, the change amount for lowering the set temperature is set to (small). Also, when the room temperature is high and the copy temperature is low, or when the room temperature is low and the copy temperature is high, the amount of change to lower the set temperature ( Usually). It's not shown again. When the sensory switch 6b during cold is pressed, the room temperature is high and the radiation temperature is high. When the room temperature is high and the radiation temperature is high, the change amount for raising the set temperature is set to (small). When the temperature is low, the change amount that raises the set temperature is set to (large), and when the room temperature is high and the copy temperature is low, or when the room temperature is low and the copy temperature is high, the change amount that raises the set temperature is set to (normal). do. This fuzzy inference is performed by a program stored in the memory 10 of the microcomputer 7.

FIG. 16 is a characteristic diagram showing an inference result of the amount of change in the set temperature performed by the set temperature change width determining means 15 of the microcomputer 7. FIG. As shown in FIG. 16, the membership function is normal (expansion is 1.0) when the room temperature is 21 [° C]. Again, the membership function is usually (= 1.0) when the radiation temperature is 21 [° C]. At this time, by applying the fuzzy rule, the set temperature range becomes 2 [deg], and the new set temperature becomes 21-2 = 19 [° C]. Similarly, the change range of the set temperature when the radiant temperature becomes 27 [° C] 2.75 [deg] and the new set temperature is 18.25 [° C]. In this manner, even at the same room temperature, the change range of the set temperature is changed by the radiation temperature, whereby the set temperature close to the human sense can be changed.

17 to 20 show an embodiment of the fifth design. FIG. 17 is a circuit configuration diagram of a heating and cooling device, where (1) is an operation switch, (2) is a first room temperature detecting device for detecting an indoor temperature of a room to be cooled and heated, and (3) is a first room temperature detecting device. An A / D converter for converting the value of (2) into a digital value, (26) is mounted on the remote control for operating the air conditioner, a second room temperature detecting element for detecting the air temperature near the remote control, (27) is the second An A / D converter for converting the value of the room temperature detection element 26 into a digital value, (6) a switch unit having a plurality of sensor switches for changing the set temperature in accordance with the user's sense, and (7) the set temperature It is a microcomputer with a means for changing the circuit, and has an input circuit 8, a CPU 9, a memory 10, and an output circuit 11. Denoted at 12 is a compressor controlled by a signal from the output circuit 11.

The switch part 6 is provided with a sensor switch 6a for operating when it is hot and a sensor switch 6b for operating when it is cold.

Fig. 18 is a block diagram showing the basic control outline, in which, reference numeral 13 denotes a first room temperature detector, 28 a second room temperature detector, and 15 a set temperature change width determining means. The amount of change in the set temperature is determined from the first room temperature detector 13 and the second room temperature detector 28 when the input signal from the switch 6 and the sensory input switch 6 are pressed. Reference numeral 16 denotes the set temperature determining means, except for the case where the change width determined by the set temperature change width determining means 15 is hot based on the first room temperature detector 13 when the sensory input switch is pressed, In addition to the case of cold, the set temperature is determined. The set temperature change width determining means 15 and the set temperature determining means 16 are constituted by, for example, a microcomputer 7.

In the flowchart of FIG. 2 (b) showing the operation of the first design, in the flowchart of the fifth design, in step 205, "detecting the air temperature near the bottom" is detected in the temperature of the remote control (second room). Temperature detection) ", and other steps are the same, and description is abbreviate | omitted.

19 is a fuzzy rule diagram for inferring a change amount of a set temperature. For example, when the first indoor temperature is high and the second indoor temperature is high from the first room temperature and the second room temperature detected when the sensor switch 6a when hot is pressed, the set temperature is lowered. When the change amount is set to (large) and the first room temperature is low and the second room temperature is low, the change amount to lower the set temperature is set to (small), and the first room temperature is high and the second room temperature is When the temperature is low or when the first room temperature is low and the second room temperature is high, the change amount for lowering the set temperature is set to (usually). Although not shown, when the sensory switch 6b during cold is pressed, the first room temperature is high and the second room temperature is high from the detected first and second room temperatures. . If the change amount to raise the set temperature is (small), and the first room temperature is low and the second room temperature is low, the change amount to raise the set temperature is (large), and the first room temperature is high. When the second room temperature is low, or when the first room temperature is low and the second room temperature is high, the change amount for raising the set temperature is set (usually). This fuzzy inference is performed by a program stored in the memory 10 of the microcomputer 7.

20 is a characteristic diagram showing the result of inference of the amount of change in the set temperature performed by the set temperature change width determining means 15 of the microcomputer 7. As shown in the figure, the membership function at room temperature of 21 [° C.] is normal (expansion is 1.0). Again, when the second room temperature is 21 [° C], the membership function is usually (certainty 1.0). At this time, by applying the fuzzy rule, the set temperature range is 2 [deg], and the new set temperature is 21-2 = 19 [° C]. Similarly, when the second indoor temperature is 27 [° C.], the change range of the set temperature is 2.75 [deg], and the new set temperature is 18.25 [° C.].

In this way, even at the same room temperature, the change range of the set temperature is changed by the second room temperature, whereby the set temperature close to the human sense can be changed.

Next, an embodiment of the sixth invention will be described with reference to the drawings. 21 to 24 show an embodiment of the sixth invention, FIG. 21 is a circuit diagram of a heating and cooling device. In the drawing, reference numeral 1 denotes an operation switch, and reference numeral 2 denotes an indoor temperature of a room to be heated and cooled. 실온 a room temperature detector for detecting, (3) an A / D converter for converting the value of the room temperature detector (2) into a digital value, and (29) a cooling and heating capability for detecting air-conditioning capacity of a cooling / heating device such as the number of revolutions of a compressor described later The detector (6) is a switch unit having a plurality of sense switches for changing the set temperature according to the user's sense, (7) is a microcomputer having a means for changing the set temperature, and an input circuit (8) and a CPU ( 9), memory 10 and output circuit 11 are included. Denoted at 12 is a compressor controlled by a signal from the output circuit 11.

The switch part 6 is provided with the sensor switch 6a which operates when it feels hot, and the sensor switch 6b which operates when it feels cold.

FIG. 22 is a block diagram showing the basic control outline, in which: (13) is a room temperature detector, (29) is a heating / cooling capacity detector of a cooling and heating device, (15) is a set temperature change width determining means, and a sensor input switch The change amount of the set temperature is determined from the room temperature detector 13 and the air-conditioning and capacity detector 29 when the input signal and the sensory input switch 6 from (6) are pressed. Numeral 16 denotes the set temperature determination means, which is a subtraction of the change width determined by the set temperature change width determining means 15, based on the room temperature detector 13 when the sense input switch is pressed, when the temperature is cold. In addition, determine the set temperature. The set temperature change width determining means 15 and the set temperature determining means 16 are constituted by, for example, a microcomputer 7.

In the flowchart of FIG. 2 (b) showing the operation of the first design, the operation of the sixth design is performed in the flowchart of FIG. Are the same, so description is omitted.

23 is a fuzzy rule diagram for inferring a change amount of a set temperature. For example, if the indoor temperature is high and the heating and cooling capability is low from the room temperature and the cooling and heating capability detected when the sensory switch 6a is pressed when it is hot, the change amount for lowering the set temperature is (large), and the indoor temperature is When the air conditioning capacity is low and the heating capacity is large, the change amount for lowering the set temperature is set to (small) .In addition, when the room temperature is high and the heating and cooling capacity is high, or when the room temperature is low and the heating and cooling capacity is low, the change amount for lowering the setting temperature is ( ). Although not shown, when the sensory switch 6b in cold is pressed, the amount of change to raise the set temperature is set to (small) when the indoor temperature is high and the cooling / heating capability is high from the detected room temperature and cooling / heating capability. When the room temperature is low and the heating and cooling capability is low, the change amount to raise the set temperature is set to (large), and when the room temperature is high and the heating and cooling capability is high, or when the room temperature and the heating and cooling capability are low. Set the change amount that raises the set temperature to (normal).

This fuzzy inference is performed by a program stored in the memory 10 of the microcomputer 7.

24 is a characteristic diagram showing an inference result of the amount of change in the set temperature performed by the set temperature change width determining means 15 of the microcomputer 7. As shown in Fig. 24, when the room temperature is 21 [° C], the membership function is normal (expansion is 1.0). Again, when the heating and cooling capacity is 50%, the membership function is usually (certainty 1.0). At this time, by applying the fuzzy rule, the set temperature range is 2 [deg], and the new set temperature is 21-2 = 19 [° C]. Similarly, when the heating and cooling capacity is 100 [%], the change in the set temperature is 1.25 [deg], and the new set temperature is 19.75 [° C.]. In this way, even at the same room temperature, the change range of the set temperature is changed by the cooling and heating ability, and thus the set temperature close to the human sense can be changed.

As described above, according to the first invention, the sensor has a sensory input function such as "hot" or "cold", and further lowers the set temperature at the time of sensory input indicating a situation, and changes the set temperature at the time of sensory input indicating a cold situation to a high level. A representative value of room temperature detected by a room temperature detector in an air conditioning and heating device. Since the set temperature change range at the time of sensor input is changed from the temperature near the floor detected by the floor temperature detector mounted near the floor rather than the room temperature detector, the room temperature is affected by the room temperature and the floor temperature that affect the user's thermal sensation. It is possible to determine the range of change of the temperature, determine the set temperature consistent with the user's senses, accurately perform the complicated change of the set temperature with a small number of times, and provide a comfortable heating and cooling device.

According to the second aspect of the invention, the set temperature change range at the time of sensory input is changed from the representative value of the room temperature detected by the room temperature detector and the floor temperature detected by the floor temperature detector mounted on the floor, and the user's sense of heat is sensed. The change of indoor temperature is decided by the influence of indoor temperature and floor temperature, so it is possible to determine the set temperature consistent with the user's senses, to perform the complicated change of the set temperature accurately with a small number of times, and to provide a comfortable air-conditioning device. can do.

According to the third invention, the set temperature change width at the time of sensory input is changed from the representative value of the room temperature detected by the room temperature detector and the wall temperature detected by the wall temperature detector mounted on the wall, and the user's heat The change of indoor temperature is determined by the room temperature and the wall temperature affecting the senses, so the user can determine the set temperature consistent with the user's senses, and it is possible to accurately perform the complicated change of the set temperature with a small number of times. Can be provided.

According to the fourth aspect of the present invention, the set temperature change range at the time of sensory input is changed from the representative value of the room temperature detected by the room temperature detector and the radiation temperature detected by the radiation temperature detector mounted on the air-conditioning unit, and the user's sense of heat is sensed. The change of indoor temperature is decided by the influence of indoor temperature and radiation temperature, so it is possible to determine the set temperature consistent with the user's senses, and to perform the complicated change of the set temperature accurately with a small number of times. Can provide.

According to the fifth aspect of the present invention, when the sensory input is performed from the first room temperature detected by the first room temperature detector and the second room temperature detected by the second room temperature detector mounted on the remote control for operating the air conditioner. By changing the temperature change range of the set temperature and determining the change range of the room temperature by the temperature near the remote control and the room temperature affecting the user's sense of heat, it is possible to determine the set temperature according to the user's sense, It is possible to accurately change the set temperature with a small number of times, and provide a comfortable air-conditioning device.

According to the sixth aspect of the present invention, the representative value of the room temperature detected by the room temperature detector, the change in the set temperature change range at the time of sensory input from the cooling and heating ability of the air conditioner, and the room temperature affecting the user's thermal sensation, and the user By determining the change in room temperature from the cooling and heating ability of the air conditioning system, which is correlated with the radiant temperature, which affects the thermal sensation, it is possible to determine the set temperature consistent with the user's senses, and to reduce the cumbersome change in the set temperature. It can perform correctly and can provide a comfortable air-conditioning apparatus.

Claims (6)

A sensory input unit for inputting a thermal sensation by the user, a room temperature detector mounted on the air-conditioning equipment to detect a representative value of the room temperature, and a floor mounted near the floor than the room temperature detector to detect a temperature near the floor The set temperature which changes the set temperature high at the time of sensory input which shows a cold situation by the output of the surrounding air temperature detector, the said sensor input part, the said room temperature detector, and the temperature detector, at the time of sensory input which shows a hot situation And a setting temperature changing width determining means for changing the changing range of the set temperature by the room temperature and the temperature measured by the temperature detector. The air conditioner according to claim 1, wherein the temperature detector is a bottom temperature detector mounted on a bottom surface to detect a temperature of the bottom. The air conditioner according to claim 1, wherein the temperature detector is a wall temperature detector mounted on a wall to detect a temperature of the wall. The air conditioner according to claim 1, wherein the temperature detector is a radiation temperature detector mounted on an air conditioner to detect radiation temperature in the room. The air conditioner according to claim 1, wherein the temperature detector is a second room temperature detector which is separated from the air conditioner and mounted on a remote control for operating the air conditioner and detects a temperature near the remote control. The air conditioner according to claim 1, wherein the air temperature detector near the floor comprises air-conditioning capability control means for controlling the air-conditioning capability so that the room temperature is equal to the set temperature.