JP6552711B2 - Air conditioner and air conditioning system - Google Patents

Description

  The present invention relates to an air conditioner and an air conditioning system using a sensor.

  Conventionally, the air conditioner uses the output data of the sensor to grasp the state of the surface temperature of the user and the room, and provides air conditioning comfortable for the user from the information of the state of the surface temperature of the user and the room The air conditioning control in the air conditioner has been changed.

  For example, in Patent Document 1, an infrared sensor detects infrared rays emitted from a human body to detect a human surface temperature to detect the presence of a user, and an ultrasonic sensor detects a distance from a reflected wave from a human body. A technique for detecting user's position information is disclosed.

  Further, Patent Document 2 discloses information on whether a user is present or absent from a reflected wave from a human body by using a Doppler sensor, or whether a user is active or resting. A technique for detecting the above is disclosed.

JP 63-143441 A JP 2011-215031 A

  However, according to the technique disclosed in Patent Document 1, the presence of the user is confirmed only by the infrared sensor. For this reason, there is a possibility of erroneous detection depending on the detection sensitivity of the infrared sensor. Moreover, an ultrasonic sensor cannot detect a user's arousal, sleep, being in bed, or getting out of bed. For this reason, even if it uses an ultrasonic sensor, comfortable air-conditioning control at the time of a user's sleep cannot be provided.

  Moreover, according to the technique of the said patent document 2, since only the Doppler sensor is used, the surface temperature of a user and a room cannot be detected. Even in the technique of Patent Literature 2, it is impossible to detect the state of the user's awakening, sleep, being in bed, or getting out of bed. For this reason, even if only a Doppler sensor is used, it is not possible to provide air conditioning control that matches the state of the room and the user existing in the room.

  This invention is made in view of the above, Comprising: It aims at obtaining the air conditioner which can detect a user's state reliably and can perform the air-conditioning control according to the user's state.

In order to solve the above-described problems and achieve the object, the present invention includes an indoor unit, an outdoor unit connected to the indoor unit, and a remote controller that transmits a control instruction command for the air conditioner to the indoor unit. It is an air conditioner. The indoor unit has a surface temperature sensor that detects the surface temperature of the room, which is the air-conditioning target space, and a reflected wave reflected by an object that transmits the transmitted wave in the room and detects the transmitted wave and the reflected wave. Radio wave sensor that detects frequency difference, uniformity of indoor surface temperature distribution based on detection result of surface temperature sensor, and frequency difference between transmitted wave and reflected wave in room based on detection result of radio wave sensor A first presence determination process for determining whether or not a user exists in the room based on both of the distribution uniformity of the room, or at least a user in the room based on the uniformity of the distribution of the surface temperature in the room And a room state determination unit that determines the state of the user in the room based on the detection result of the radio wave sensor. The indoor unit includes an information processing unit that determines a control setting condition of the air conditioner according to the indoor user state based on the determination result of the indoor user state in the indoor state determination unit, and an information processing unit. and the air conditioning state control unit for controlling the air conditioner based on the condition of the control settings of the determined air conditioner, Ru comprising a. The indoor state determination unit can switch between the first presence determination process and the second presence determination process. In the first presence determination process, the indoor state determination unit is configured such that the uniformity of the distribution of the surface temperature of the room and the uniformity of the distribution of the frequency difference between the transmitted wave and the reflected wave are uniform throughout the room. If it is not, it is determined that the user is present in the room, and the uniformity of the distribution of the surface temperature of the room and the uniformity of the distribution of the frequency difference between the transmitted wave and the reflected wave are both uniform throughout the room. In some cases, it is determined that the user is absent from the room. In the second presence determination process, the indoor state determination unit determines that the user is absent from the room when the uniformity of the distribution of the surface temperature of the room is uniform throughout the room, If the uniformity of the surface temperature distribution and the uniformity of the frequency difference distribution between the transmitted wave and the reflected wave are not uniform throughout the room, it is determined that the user is present in the room, If the uniformity of the surface temperature distribution is not uniform throughout the room, and the uniformity of the frequency difference distribution from the reflected wave is uniform throughout the room, the user is not present in the room. Determine that there is .

  The air conditioner according to the present invention has an effect that air-conditioning control according to the user's state is possible by reliably detecting the user's state.

The block diagram which shows the structure of the air conditioner concerning Embodiment 1 of this invention. The block diagram which shows the main function structures of the air conditioner concerning Embodiment 1 of this invention. The figure which shows an example of the hardware constitutions of the processing circuit concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the 1st presence determination process in the air conditioner concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the 2nd presence determination process in the air conditioner concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the user's respiration determination process in the air conditioner concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the user's sleep determination process in the air conditioner concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the user's presence determination process in the air conditioner concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the user's body movement determination process in the air conditioner concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the temperature setting process of the 1st air conditioning control at the time of the user's absence in the air conditioner concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the temperature setting process of the 2nd air conditioning control at the time of the absence of the user in the air conditioner concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the temperature setting process of the air-conditioning control in case the user is present indoors in the air conditioner concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the temperature setting process of the air-conditioning control in case the user is leaving the room indoors in the air conditioner concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the temperature setting process of air-conditioning control when a user is sleeping indoors and there is little body movement in the air conditioner concerning Embodiment 1 of this invention. The flowchart which shows the procedure of the temperature setting process of air-conditioning control in case the user is sleeping indoors and there are many body movements in the air conditioner concerning Embodiment 1 of this invention. The block diagram which shows the main functional structures of the air conditioning system concerning Embodiment 2 of this invention. The block diagram which shows the main function structures of the air conditioner concerning Embodiment 2 of this invention.

  Hereinafter, an air conditioner and an air conditioning system according to an embodiment of the present invention will be described in detail with reference to the drawings. The present invention is not limited by the embodiment.

Embodiment 1
FIG. 1 is a configuration diagram showing a configuration of an air conditioner 10 according to Embodiment 1 of the present invention. FIG. 2 is a block diagram illustrating a main functional configuration of the air conditioner 10 according to the first embodiment of the present invention. In FIG. 2, the flow of the data signal is indicated by a solid line, and the flow of the control signal is indicated by an alternate long and short dash line. As shown in FIG. 1, the air conditioner 10 according to the first embodiment includes an indoor unit 11, an outdoor unit 12, a refrigerant pipe 13, and a remote controller 14. The air conditioner 10 forms one complete refrigeration cycle with the indoor unit 11 and the outdoor unit 12. The air conditioner 10 uses a refrigerant that circulates between the indoor unit 11 and the outdoor unit 12 through the refrigerant pipe 13 to transfer heat between indoor air and outdoor air that are air-conditioning target spaces. To achieve air conditioning in the room. That is, the indoor unit 11 and the outdoor unit 12 are connected by a refrigerant pipe 13, and the pressure of the refrigerant flowing in the refrigerant pipe 13 is changed by a compressor provided in the outdoor unit 12 so that air conditioning is achieved by heat absorption and heat dissipation of the refrigerant. Do.

  The outdoor unit 12 is connected to the indoor unit 11 by a refrigerant pipe 13. The outdoor unit 12 can communicate with the indoor unit 11 via a communication line (not shown). The outdoor unit 12 is provided with an outside air temperature sensor 15 which is a temperature sensor, in addition to a normal functional unit necessary as equipment outside the air conditioning, and the outside air temperature sensor 15 can measure the outside air temperature. The outside air temperature sensor 15 repeatedly detects the outside air temperature at a prescribed cycle set by the air conditioning state control unit 25 or at a prescribed cycle set in advance in the outside air temperature sensor 15. Then, the outside air temperature sensor 15 transmits the detected outside air temperature information to the indoor state determination unit 23 of the indoor unit 11. The outside air temperature sensor 15 normally operates at all times when the air conditioner 10 is driven.

  The indoor unit 11 can communicate with the remote controller 14 by wireless communication. Thereby, the indoor unit 11 can receive control instruction information such as temperature setting input to the remote controller 14 by a user in the room from the remote controller 14 at a receiving unit (not shown). Thereby, the indoor unit 11 can change various control settings in the air conditioner 10. The indoor unit 11 may communicate with the remote controller 14 by wired communication. The indoor unit 11 includes an indoor unit switch 17 that can set various control instructions for the air conditioner 10, and the control setting can be changed by setting the indoor unit switch 17. is there. The indoor unit 11 includes an indoor temperature sensor 16 that is a temperature sensor, and the indoor temperature sensor 16 can measure the indoor temperature.

  The indoor unit 11 also has a surface temperature sensor 21 for detecting the surface temperature of the room and the surface temperature of the user present in the room in a noncontact manner, in addition to a normal functional unit necessary as an air conditioning room facility. An indoor state determination unit 23 that determines the indoor state or the position and state of the user in the room using the radio wave sensor 22 that detects the position of the user in the room, the information of the surface temperature sensor 21 and the information of the radio wave sensor 22. And Further, the indoor unit 11 controls the air conditioner such as temperature from the indoor condition determined by the information processing unit 24 that determines the indoor condition and the user's condition from the information of the indoor condition determination unit 23 An air conditioning state control unit 25 that determines the state and a storage unit 26 that stores the control state of the air conditioner determined by the air conditioning state control unit 25 are provided.

  The surface temperature sensor 21 is an infrared sensor, and detects the surface temperature of a plurality of predetermined detection locations in the room according to a control signal transmitted from the air conditioning state control unit 25. The surface temperature sensor 21 repeatedly detects the surface temperature at a specified cycle set by the air conditioning state control unit 25 or at a specified cycle set in advance in the surface temperature sensor 21. Normally, the surface temperature sensor 21 is always operating when the air conditioner 10 is driven. Then, the surface temperature sensor 21 transmits information on the surface temperatures of a plurality of detection points in the room detected in one detection cycle to the room state determination unit 23. A plurality of surface temperature sensors 21 may be provided. The surface temperature sensor 21 is not limited to the infrared sensor, and other sensors can be used as long as the surface temperature of the room can be detected without contact.

  The radio wave sensor 22 transmits a transmission wave to a number of predetermined detection locations in the room in accordance with a control signal transmitted from the air conditioning state control unit 25, and detects a reflected wave of the transmission wave. That is, the radio wave sensor 22 transmits a microwave that is a transmission wave to an object present in the room, and receives a reflected wave reflected from the object. If there is an object in the room, the transmission wave is reflected. When the object is moving, a frequency difference is generated between the transmitted wave and the reflected wave. The difference of this frequency changes according to the moving speed of the object. For this reason, when there is a user in the room, the radio wave sensor 22 can detect a difference in frequency according to the position of the user and the activity status of the user. The radio wave sensor 22 generates frequency difference information that is information on the frequency difference between the transmission wave and the detected reflected wave, and transmits the frequency difference information to the indoor state determination unit 23. The radio wave sensor 22 operates at a predetermined cycle set by the air conditioning state control unit 25 or a predetermined cycle set in advance. A plurality of radio wave sensors 22 may be provided.

  The difference in frequency between the transmitted wave and the reflected wave is set as a unique value threshold for each user activity state, so that the user state can be detected. That is, by using the threshold value and the frequency difference information, the indoor state determination unit 23 determines whether the user is present or absent in the room, or the user is breathing if the user is present. Whether the user is apnea, if the user is breathing, the user is awake or sleeping, if the user is awake, the user is on bed or is leaving, or the user is sleeping If it is in the middle, it is possible to detect whether the user's body movement such as turning over is small or small. By storing the threshold value for each user activity state in the storage unit 26, the indoor state determination unit 23 can be used to determine the user state when the frequency difference information is acquired from the radio wave sensor 22.

  The indoor state determination unit 23 uses the temperature information and the frequency difference information to determine whether a user is present or absent in the room. The indoor state determination unit 23 may perform presence determination using one of the temperature information and the frequency difference information, or may perform presence determination using both the temperature information and the frequency difference information. Good. The indoor surface temperature information and frequency difference information transmitted to the indoor state determination unit 23 are then transmitted to the storage unit 26 via the information processing unit 24 and accumulated in the storage unit 26.

  The indoor state determination unit 23 uses the surface temperature information of the plurality of detection points received from the surface temperature sensor 21 to calculate the user's temperature from the temperature difference between the user's temperature and the user's ambient temperature when the user exists in the room. The presence of can be detected. That is, the indoor state determination unit 23 can detect the presence of the user when there are different temperatures having a specified temperature difference in the surface temperatures of the plurality of detection points detected in one detection cycle.

  The indoor state determination unit 23 determines the state of the user in the room based on the frequency difference information transmitted from the radio wave sensor 22 and a specified threshold value. The indoor state determination unit 23 determines information on the presence / absence in the room, breathing, apnea, awakening, sleep, bedtime, bed departure, many body movements, little body movement as the state of the user in the room . The indoor state determination unit 23 transmits information on the determined state of the user in the room to the information processing unit 24 and to the storage unit 26 for storage.

  The information processing unit 24 is a condition for control setting of the air conditioner 10 according to the indoor user's state, based on the information on the indoor user's state transmitted from the indoor state determination unit 23 and the prescribed threshold value, That is, the presence / absence of driving and the set temperature of the air conditioning in the room are determined, and the determined conditions are transmitted to the air conditioning state control unit 25.

  The air conditioning state control unit 25 controls overall air conditioning control in the air conditioner 10, including control of the outside air temperature sensor 15, the surface temperature sensor 21, the radio wave sensor 22, the indoor state determination unit 23, the information processing unit 24, and the storage unit 26. I do. Further, the air conditioning state control unit 25 uses the condition of the control setting of the air conditioner 10 received from the information processing unit 24 according to the indoor user's condition, that is, the information of the presence / absence of driving and the information of the indoor air conditioning set temperature. The air conditioning temperature setting is changed based on the air conditioning control in the air conditioner 10 according to the changed air conditioning temperature setting.

  The memory | storage part 26 memorize | stores the various information regarding the control state of the air conditioner 10, such as the indoor set temperature in control of the air conditioner 10 which is control information of the air conditioner 10 in the air-conditioning state control part 25. FIG.

  Usually, the indoor state determination unit 23, the information processing unit 24, the air conditioning state control unit 25, and the storage unit 26 are configured by one or a plurality of microcomputers. That is, the air-conditioning state control unit 25 is realized as a processing circuit having a hardware configuration illustrated in FIG. 3, for example. FIG. 3 is a diagram illustrating an example of a hardware configuration of the processing circuit according to the first embodiment of the present invention. The air conditioning state control unit 25 is realized, for example, when the processor 101 illustrated in FIG. 3 executes a program stored in the memory 102. The storage unit 26 is realized by the memory 102. A plurality of processors and a plurality of memories may cooperate to realize the above function. Note that a part of the functions of the air conditioning state control unit 25 may be mounted as an electronic circuit, and the other parts may be realized using the processor 101 and the memory 102. Further, one or more of the indoor state determination unit 23 and the information processing unit 24 may be configured to be realized by the processor 101 executing a program stored in the memory 102 in the same manner. Further, the processor and the memory for realizing one or more of the indoor state determination unit 23 and the information processing unit 24 may be the same as the processor and the memory for realizing the air conditioning state control unit 25, or different It may be a processor and a memory. The storage unit 26 is realized by the memory 102.

  Next, the presence determination process in which the air conditioner 10 determines whether or not the user exists in the room or not is described. FIG. 4 is a flowchart illustrating a procedure of the first presence determination process in the air conditioner 10 according to the first embodiment of the present invention.

  The indoor state determination unit 23 receives and acquires information on the indoor surface temperature from the surface temperature sensor 21 in step S11. In step S12, the indoor state determination unit 23 confirms the distribution of the indoor surface temperature based on the information on the indoor surface temperature, and confirms whether the indoor surface temperature is uniform.

  The indoor state determination unit 23 receives and acquires the frequency difference information from the radio wave sensor 22 in step S13. Then, in step S14, the indoor condition determination unit 23 confirms the distribution of the frequency difference between the transmission wave and the reflected wave based on the frequency difference information, and the difference in the frequency between the transmission wave and the reflected wave in the room is uniform. Check if it exists.

  In step S15, the indoor state determination unit 23 has both the surface temperature of the room confirmed in step S12 and the difference in frequency between the transmitted wave and the reflected wave detected in step S14 uniform over the entire room. It is determined whether or not.

  If the indoor surface determination unit 23 determines that the surface temperature of the room and the difference between the frequency of the transmission wave and the frequency of the reflected wave are not uniform over the entire room, that is, No in step S15, the room in step S16. The state determination unit 23 determines that the user exists in the room. The indoor state determination unit 23 determines that there is a user in the room when at least one of the room surface temperature and the frequency difference between the transmitted wave and the reflected wave is not uniform throughout the room. It is also possible.

  If the indoor surface temperature and the frequency difference between the transmitted wave and the reflected wave are both uniform throughout the room, that is, if Yes in step S15, the indoor state determination unit 23 performs step S17. It is determined that the user is absent in the room.

  Normally, if the indoor surface temperature is uniform throughout the room, the user is likely to be absent. However, for example, when several days have passed since the user died in the room, or when the user exists inside the heat insulating material or the heat insulating sheet that shields the temperature, even if the user exists in the room The surface temperature in the room detected by the surface temperature sensor 21 becomes uniform. For this reason, the presence of the user in the room cannot be accurately detected only by the information on the room surface temperature detected by the surface temperature sensor 21.

  On the other hand, in the frequency of the reflected wave detected by the radio wave sensor 22, when the user exists in the room, there is a difference between the frequency of the reflected wave from the user and the frequency of the reflected wave from the user's surroundings. Occur. For this reason, it is possible to detect the presence of the user in the room only with the frequency difference information of the radio wave sensor 22. Then, by simultaneously checking the detection result of the indoor surface temperature in the surface temperature sensor 21 and the frequency difference information by the radio wave sensor 22, it is possible to more reliably determine that the user exists in the room. Further, even when the detection sensitivity of one of the surface temperature sensor 21 and the radio wave sensor 22 decreases due to some cause such as a malfunction, it is possible to determine that the user exists in the room.

  In the above configuration, for example, information as to whether or not a single-living elderly person with little communication with the surroundings exists in the room, or information as to whether or not it is a Charge Coupled Device (CCD) camera, etc. It is possible to detect only an apparatus such as an air conditioner that is frequently used in daily life without using an apparatus that may infringe the privacy of the user. It can also be used for confirming the existence of a resident in a room or for confirming the existence of a living in a group living place such as a nursing home or a dormitory.

  Next, another existence determination process will be described. FIG. 5 is a flowchart showing the procedure of the second presence determination process in the air conditioner 10 according to the first embodiment of the present invention. In FIG. 5, the same steps as those in the flowchart of FIG. 4 are denoted by the same step numbers.

  The indoor state determination unit 23 receives and acquires information on the indoor surface temperature from the surface temperature sensor 21 in step S11. In step S12, the indoor state determination unit 23 confirms the distribution of the indoor surface temperature based on the information on the indoor surface temperature, and confirms whether the indoor surface temperature is uniform.

  Next, in step S21, the indoor state determination unit 23 determines whether the indoor surface temperature confirmed in step S12 is uniform over the entire room. If the indoor surface temperature is uniform throughout the room, that is, if the answer is Yes in step S21, the indoor state determination unit 23 determines in step S24 that there is no user in the room.

  On the other hand, if the indoor surface temperature is not uniform over the entire room, that is, if No in step S21, the indoor state determination unit 23 receives and acquires the frequency difference information from the radio wave sensor 22 in step S13. Then, in step S14, the indoor condition determination unit 23 confirms the distribution of the difference in frequency between the transmission wave and the reflected wave based on the frequency difference information, and the difference in frequency between the transmission wave and the reflected wave in the room is uniform. Check whether or not.

  Next, in step S22, the indoor state determination unit 23 determines whether or not the difference in frequency between the transmission wave confirmed in step S14 and the detected reflected wave is uniform throughout the room. If the difference between the frequencies of the transmitted wave and the reflected wave is uniform over the entire room, that is, if Yes in step S22, the indoor state determination unit 23 determines in step S24 that there is no user in the room. Do.

  On the other hand, if the difference in frequency between the transmitted wave and the reflected wave is not uniform over the entire room, that is, if No in step S22, the indoor state determination unit 23 determines in step S23 that the user exists in the room. .

  Then, even when the second presence determination process described above is performed, the user is present in the room by simultaneously checking the detection of the indoor surface temperature by the surface temperature sensor 21 and the frequency difference information by the radio wave sensor 22. This can be determined more reliably.

  The first presence determination process illustrated in FIG. 4 and the second presence determination process illustrated in FIG. 5 can be switched by the control of the air conditioning state control unit 25. When instructing execution of the first presence determination process, the air conditioning state control unit 25 transmits a first presence determination process instruction signal instructing execution of the first presence determination process to the indoor state determination unit 23. Moreover, the air-conditioning state control part 25 transmits the 2nd presence determination process instruction signal which instruct | indicates execution of a 2nd presence determination process to the indoor state determination part 23, when implementing a 2nd presence determination process.

  When the indoor state determination unit 23 is set to execute the first presence determination process and receives the second presence determination process instruction signal, the indoor state determination unit 23 performs the second presence determination process thereafter. Further, when the indoor state determination unit 23 is set to execute the second presence determination process and receives the first presence determination process instruction signal, the indoor state determination unit 23 performs the first presence determination process thereafter. Do. Then, for example, in the case where it is necessary to confirm the survival of the user, the first existence determination process is executed, and it is not necessary to confirm the survival of the user and it can be determined whether the user exists in the room. May be switched in accordance with the application, such as executing the second presence determination process.

  The first presence determination process and the second presence determination process may be set by the remote controller 14 and can be set by the indoor unit switch 17 during the installation of the air conditioner 10. May be. In any case, it can be realized by the indoor state determination unit 23 executing a program for executing the first presence determination process or a program for performing the second presence determination process, which is built in the storage unit 26.

  If the indoor state determination unit 23 determines that the user is present in the room in the first presence determination process or the second presence determination process, then the user is present in the room in any state. Determine if it exists. The contents to be determined are as follows. (1) Whether the user is breathing or apnea. (2) Whether the user is awake or sleeping. (3) If the user is awake, is the user in bed or out of bed? (4) If the user is sleeping, is the user in a state where there is a lot of body movement or in a state where there is little body movement?

  Next, after the air conditioner 10 determines that the user is present in the room, the user's breath determination process for determining whether the user existing in the room is breathing or apnea is described. Do. FIG. 6 is a flowchart showing the procedure of the user breathing determination process in the air conditioner 10 according to the first embodiment of the present invention.

  First, the indoor condition determination unit 23 executes the first presence determination processing shown in FIG. 4 or the second presence determination processing shown in FIG. 5 as the presence determination processing in step S31, and the user Is determined to exist.

  Next, the indoor state determination part 23 receives and acquires frequency difference information from the radio wave sensor 22 in step S33. In step S34, the indoor state determination unit 23 compares the first threshold value with the acquired frequency difference information, and determines in step S35 whether the indoor frequency difference is equal to or greater than the first threshold value. In addition, it is also possible to use the frequency difference information acquired in the presence determination process of step S31 instead of the frequency difference information in step S33.

  The first threshold is a representative value of the difference in frequency between the transmitted wave transmitted to the user and its reflected wave when the user present in the room is breathing, is the user breathing? It is a reference value for determining whether it is apnea or apnea. The indoor state determination unit 23 reads and uses the first threshold value stored in advance in the storage unit 26. The first threshold value may be stored in a storage unit included in the indoor state determination unit 23.

  If the acquired frequency difference in the room is equal to or greater than the first threshold value, that is, if Yes in step S35, the room state determination unit 23 determines in step S36 that the user is breathing. On the other hand, when the acquired frequency difference in the room is less than the first threshold, that is, in the case of No in step S35, the indoor state determination unit 23 determines that the user is apnea in step S37.

  When the user is breathing, since the user has a slight body movement, a change appears in the frequency difference detected by the radio wave sensor 22. The changed frequency difference value is preset and stored as a threshold value for the user's breathing. Then, by comparing this threshold value with the acquired frequency difference information, it is possible to determine whether the user is breathing or apnea. Therefore, when the acquired frequency difference is equal to or greater than the first threshold, it is determined that the user is breathing, and when the acquired frequency difference is less than the first threshold, the user is determined to be apnea .

  Next, a user sleep determination process in which the air conditioner 10 determines whether the user is awake or sleeping is described. If the indoor state determination unit 23 determines that the user is breathing in the respiration determination process of the user, then the indoor state determination unit 23 determines whether the user is awake or sleeping. FIG. 7 is a flowchart showing the procedure of the user sleep determination process in the air conditioner 10 according to the first embodiment of the present invention.

  First, the indoor state determination unit 23 executes the presence determination process and determines that the user is present indoors, and then executes the breathing determination process of the user shown in FIG. 6 in step S41, and the user in step S42. Is determined to be breathing.

  Next, the indoor state determination part 23 receives and acquires frequency difference information from the radio wave sensor 22 in step S43. And the indoor state determination part 23 compares the 2nd threshold value with the acquired frequency difference information in step S44, and determines whether the indoor frequency difference is more than a 2nd threshold value in step S45. In addition, it is also possible to use the frequency difference information acquired from the presence determination process to the respiration determination process instead of the frequency difference information in step S43.

  The second threshold is a representative numerical value of the frequency difference between the transmitted wave transmitted to the user and the reflected wave when the user existing in the room is awake, and the user is awake. Or a reference value for determining whether the user is sleeping. The indoor state determination unit 23 reads and uses the second threshold value stored in advance in the storage unit 26. In addition, the 2nd threshold value of a frequency difference may be memorize | stored in the memory | storage part with which the indoor state determination part 23 is equipped inside.

  If the acquired frequency difference is greater than or equal to the second threshold, that is, if Yes in step S45, the indoor state determination unit 23 determines in step S46 that the user is awake. On the other hand, when the acquired frequency difference in the room is less than the second threshold, that is, in the case of No in step S45, the indoor state determination unit 23 determines in step S47 that the user is sleeping.

  When the user is awake, the body movement is increased compared to the time of sleep, such as changing the direction of the body or getting up, so that a change appears in the frequency difference detected by the radio wave sensor 22. The changed frequency difference value is preset and stored as a threshold value when the user is awake. Then, by comparing this threshold value with the acquired frequency difference information, it is possible to determine whether the user is awake or sleeping. Therefore, when the acquired frequency difference is equal to or greater than the second threshold, it is determined that the user is awake, and when the acquired frequency difference is less than the second threshold, the user is determined to be sleeping. Ru.

  Also, if you are awake, you will have more actions such as changing your body orientation and getting up compared to sleeping. And the value of the changed frequency difference is different for each body movement. For this reason, as a comparison between the acquired frequency difference and the threshold value, threshold values of different frequency differences corresponding to each body motion are stored in the storage unit 26 as the second threshold value, and the acquired frequency difference is compared with each threshold value. The determination may be made by performing.

  Next, a description will be given of a user's presence determination process in which the air conditioner 10 determines whether the user is in the floor or is leaving the floor. When the indoor state determination unit 23 determines that the user is awake during the sleep determination process of the user, the indoor state determination unit 23 thereafter determines whether the user is in bed or out of bed. FIG. 8 is a flowchart showing the procedure of the user presence determination process in the air conditioner 10 according to the first embodiment of the present invention.

  First, after performing the presence determination process and the user breath determination process described above, the indoor state determination unit 23 performs the user sleep determination process shown in FIG. 7 in step S51, and the user is awake in step S52. It is determined that

  Next, the indoor state determination part 23 receives and acquires frequency difference information from the radio wave sensor 22 in step S53. Then, the indoor state determination unit 23 compares the third threshold with the acquired frequency difference information in step S54, and determines in step S55 whether the frequency difference in the room is equal to or greater than the third threshold. In addition, it is also possible to use the frequency difference information acquired from the presence determination process to the sleep determination process instead of the frequency difference information in step S53.

  The third threshold is a representative numerical value of the difference in frequency between the transmitted wave transmitted to the user and the reflected wave when the user existing in the room is in the bed, and the user is in the bed Or a reference value for determining whether the person is getting out of bed. The indoor state determination unit 23 reads and uses the third threshold value stored in advance in the storage unit 26. In addition, the 3rd threshold value of a frequency difference may be memorize | stored in the memory | storage part with which the indoor state determination part 23 is equipped inside.

  If the acquired frequency difference is greater than or equal to the third threshold, that is, if Yes in step S55, the indoor state determination unit 23 determines in step S56 that the user is getting out of bed. On the other hand, if the acquired frequency difference is less than the third threshold, that is, if No in step S55, the indoor state determination unit 23 determines that the user is in bed in step S57.

  When the user leaves the bed, the movement of the room increases, such as walking in the room, sitting on a chair, eating, etc., so that the movement of the radio wave sensor 22 changes, as physical movement increases. The changed frequency difference value is preset and stored as a threshold value when the user is in bed. Then, by comparing this threshold value with the acquired frequency difference information, it is possible to determine whether the user is in bed or out of bed. Therefore, when the acquired frequency difference is greater than or equal to the third threshold, it is determined that the user is getting out of bed, and when the acquired frequency difference is less than the third threshold, the user is determined to be in bed. Be done.

  In addition, when leaving the bed, the behavior such as walking in the room, sitting on a chair, eating, etc. is increased as compared with when the user is in bed. The value of the changed frequency difference is different for each of these body movements. For this reason, as a comparison between the acquired frequency difference and the threshold value, a plurality of different frequency difference threshold values corresponding to each body motion are stored in the storage unit 26 as a third threshold value, and the acquired frequency difference is compared with each threshold value. The determination may be made by performing.

  Next, the user's body movement determination process in which the air conditioner 10 determines whether the user's body movement during sleep is high or low is described. When it is determined in the user's presence determination process that the user is in the floor, the indoor state determination unit 23 determines whether the user's body movement is large or the body movement is small. FIG. 9 is a flowchart showing a procedure of a user's body movement determination process in the air conditioner 10 according to the first embodiment of the present invention.

  First, after performing the presence determination process and the user breathing determination process described above, the indoor state determination unit 23 performs the user sleep determination process shown in FIG. 7 in step S61, and the user is sleeping in step S62. It is determined that

  Next, the indoor state determination part 23 receives and acquires frequency difference information from the radio wave sensor 22 in step S63. And the indoor state determination part 23 compares the 4th threshold value with the acquired frequency difference information in step S64, and determines whether the indoor frequency difference is more than the 4th threshold value of a frequency difference in step S65. .

  The fourth threshold is a representative value of the difference in frequency between the transmitted wave transmitted to the user and its reflected wave when the user existing in the room is sleeping, and the user's body movement is large Or a reference value for determining whether the user's body movement is small. The indoor state determination unit 23 reads and uses the fourth threshold value of the frequency difference stored in advance in the storage unit 26. In addition, the 4th threshold value of a frequency difference may be memorize | stored in the memory | storage part with which the indoor state determination part 23 is equipped inside.

  If the acquired frequency difference is greater than or equal to the fourth threshold value, that is, if Yes in step S65, the indoor state determination unit 23 determines in step S66 that the user has a lot of body movement. On the other hand, if the acquired current frequency difference is less than the fourth threshold value, that is, if No in step S65, the indoor state determination unit 23 determines in step S67 that the user's body movement is small. In addition, it is also possible to use the frequency difference information acquired from the presence determination process to the sleep determination process instead of the frequency difference information in step S63.

  The fact that the user has a lot of body movement means that the number of movements of the user is greater than a prescribed reference value, such as turning over or moving while not waking up. The fact that the user's body movement is small means that the number of times the user moves is less than a prescribed reference value. When there is a user's body movement, a change appears in the frequency difference detected by the radio wave sensor 22 due to the body movement. This changed frequency difference is set and stored in advance as a threshold value when there are many user movements. Then, by comparing the threshold value with the acquired frequency difference, it is possible to determine whether the user has a lot of body movement or a body movement. Therefore, it is determined that the user's body movement is large when the acquired frequency difference is equal to or greater than the fourth threshold, and it is determined that the user's body movement is small when the current frequency difference is less than the fourth threshold. Ru.

  A state in which the user has a lot of body movement at the time of sleep may be a case where the user's sleep is shallow. However, since the ambient temperature of the user is high, the user may feel hot. That is, it can be considered that the user's sleep state is not a comfortable sleep state. Conversely, when the user's physical activity is low during sleep, the user's sleep may be deep, but the user's ambient temperature is an appropriate temperature, and the user's sleep is considered a comfortable sleep. be able to. Therefore, the prescribed reference value is a reference value for determining whether or not the user's sleep state is a comfortable sleep state.

  In addition, when the user's body movement is large, behavior such as turning over or moving although not happening is increased. The value of the changed frequency difference is different for each body movement. For this reason, as a comparison between the acquired frequency difference and the threshold value, a plurality of different frequency difference threshold values corresponding to each body motion are stored in the storage unit 26 as the fourth threshold value, and the acquired frequency difference is compared with each threshold value. The determination may be made by performing.

  When the indoor state determination unit 23 performs the above-described process, the state of the user in the room, that is, the presence or absence of the user, breathing or apnea, awakening or sleeping, presence or absence in bed, a large amount of movement or After determining the state with less body movement, the control setting of the air conditioner 10 that matches the user's state is determined by the information processing unit 24 based on the determined result information.

  Next, temperature setting processing for air conditioning control when the user is absent in the room of the air conditioner 10 will be described. FIG. 10 is a flowchart showing the procedure of the temperature setting process of the first air conditioning control when the user is absent in the air conditioner 10 according to the first embodiment of the present invention.

  First, the indoor state determination unit 23 executes the first presence determination process shown in FIG. 4 or the second presence determination process shown in FIG. 5 as the presence determination process in step S71. Is determined to be absent.

  Next, the indoor state determination unit 23 receives and acquires information on the outdoor air temperature from the outdoor air temperature sensor 15 in step S73. Further, the indoor state determination unit 23 receives and acquires information on the indoor surface temperature from the indoor temperature sensor 16 in step S74. In step S75, the indoor state determination unit 23 compares the absolute value of the temperature difference between the indoor indoor temperature and the outdoor outdoor temperature with the fifth threshold value, and calculates the absolute temperature difference between the indoor temperature and the outdoor air temperature. In step S76, it is determined whether the value is larger than the fifth threshold. In addition, it is also possible to use the information on the indoor surface temperature acquired in the presence determination process instead of the information on the indoor surface temperature in step S74.

  The fifth threshold value of the temperature difference is a reference value for determining whether or not the temperature difference between the outdoor and indoors when the user is not present in the room is excessive. The indoor state determination unit 23 reads out and uses the fifth threshold value stored in advance in the storage unit 26. The fifth threshold value may be stored in a storage unit provided in the indoor state determination unit 23.

  When the user is not present in the room, there is no need to air-condition the room excessively more than necessary. That is, when the user does not exist in the room, it is not necessary to cool or warm the room more than necessary. This is equivalent to not making an excessive difference between the outside air temperature and the room temperature. Therefore, a threshold value in a state where the temperature difference between the outside air temperature and the room temperature is excessive is set and stored in advance. Then, by comparing this threshold value with the absolute value of the temperature difference between the outside air temperature and the room temperature, it is possible to determine whether or not the temperature difference between the outside air temperature and the room temperature is excessive. . Therefore, when the absolute value of the temperature difference between the outside air temperature and the room temperature is larger than the fifth threshold value, it is determined that the temperature difference between the outside air temperature and the room temperature is excessive, and the outside air temperature and the room temperature. If the absolute value of the temperature difference between the second and third is equal to or less than the fifth threshold, it is determined that the temperature difference between the outside air temperature and the room temperature is not excessive.

  If the absolute value of the temperature difference between the outside air temperature and the room temperature is equal to or smaller than the fifth threshold value of the temperature difference, that is, if No in step S76, the series of air conditioning control temperature setting processing ends.

  On the other hand, when the absolute value of the temperature difference between the outside air temperature and the room temperature is larger than the fifth threshold value, that is, when the answer is Yes in Step S76, the room state determination unit 23 in Step S77 determines the outside air temperature and the room temperature. Temperature difference excess information to the effect that the temperature difference is large is transmitted to the information processing unit 24. When the information processing unit 24 receives the temperature difference excess information, the information processing unit 24 reduces the temperature difference between the outside air temperature and the room temperature based on the temperature difference excess information and the current air conditioning set temperature. The set temperature of the indoor air conditioning that is brought close to the outside air temperature is determined. The information processing unit 24 acquires the current setting temperature of air conditioning from the storage unit 26 and uses it.

  After the information processing unit 24 determines the temperature setting of the air conditioning control of the air conditioner according to the user's state as described above, the information processing unit 24 uses the air conditioning state control unit 25 to provide information on the determined temperature setting of the air conditioning. Send to. The air conditioning state control unit 25 changes the temperature setting of the air conditioning control in the storage unit 26 based on the received information on the set temperature of the air conditioning, controls the compressor of the outdoor unit 12 according to the changed set temperature, and the air conditioner The air conditioning control at 10 is performed. The change period of the temperature setting in the storage unit 26 is stored in advance in the storage unit 26.

  When the user is not present in the room, there is no need to excessively air-condition the room, so energy saving can be achieved by changing the setting of the air conditioning temperature of the room to a temperature that reduces the temperature difference between the outside air temperature and the room temperature. Can be realized.

  Next, temperature setting processing for other air conditioning control when the user is absent in the room of the air conditioner 10 will be described. FIG. 11 is a flowchart showing the procedure of the temperature setting process of the second air conditioning control when the user is absent in the air conditioner 10 according to the first embodiment of the present invention.

  First, the indoor state determination unit 23 executes the first presence determination process shown in FIG. 4 or the second presence determination process shown in FIG. 5 as the presence determination process in step S81, and the user enters the room indoors in step S82. Is determined to be absent. After determining that the user is not present indoors in step S82, the indoor state determination unit 23 determines control information for ending the operation of the air conditioning in step S83, and is control information for instructing the end of the operation of the air conditioning The air conditioning end instruction information is transmitted to the information processing unit 24. When the air conditioning end instruction information is received, the information processing unit 24 transmits the air conditioning end instruction information to the air conditioning state control unit 25. Based on the received air conditioning end instruction information, the air conditioning state control unit 25 performs control to end indoor air conditioning rather than changing the temperature setting.

  When the user does not exist in the room, there is no need to air-condition the room, so that more effective energy saving can be realized by performing control to end the air-conditioning in the room.

  The first temperature setting process shown in FIG. 10 and the second temperature setting process shown in FIG. 11 can be switched by the control of the air conditioning state control unit 25. When instructing execution of the first temperature setting process, the air-conditioning state control unit 25 transmits a first temperature setting process instruction signal instructing execution of the first temperature setting process to the indoor state determination unit 23. . Moreover, the air-conditioning state control part 25 transmits the 2nd temperature setting instruction | indication signal which instruct | indicates execution of a 2nd temperature setting process to the indoor state determination part 23, when implementing a 2nd temperature setting process.

  When the indoor temperature determination unit 23 is set to execute the first temperature setting process and receives the second temperature setting process instruction signal, the indoor state determination unit 23 thereafter performs the second temperature setting process. . In addition, when the indoor temperature determination unit 23 is set to execute the second temperature setting process, and receives the first temperature setting process instruction signal, the indoor state determination unit 23 performs the first temperature setting process thereafter. carry out.

  Next, temperature setting processing of air conditioning control when the user is present in the room in the air conditioner 10 will be described. FIG. 12 is a flowchart illustrating a procedure of temperature setting processing for air conditioning control when a user is present indoors in the air conditioner 10 according to the first embodiment of the present invention.

  First, the indoor state determination unit 23 performs the presence determination process illustrated in FIG. 8 as the presence determination process in step S91 after performing the presence determination process, the user breath determination process, and the user sleep determination process described above. Then, in step S92, it is determined that the user is in the room.

  Next, the indoor state determination part 23 receives the information of the indoor surface temperature from the surface temperature sensor 21 in step S93, and acquires the information of the surface temperature of the user from the inside. Next, the indoor condition determination unit 23 receives and acquires information on the indoor temperature from the indoor temperature sensor 16 in step S94. Then, in step S95, the indoor state determination unit 23 compares the absolute value of the temperature difference between the user's surface temperature and the room temperature with the sixth threshold value to determine the temperature difference between the user's surface temperature and the room temperature. In step S96, it is determined whether the absolute value is larger than the sixth threshold. Note that, instead of the information on the indoor surface temperature in step S93, it is also possible to use the information on the indoor surface temperature acquired in the presence determination process.

  The sixth threshold value of the temperature difference is a reference value for determining whether or not the temperature difference between the surface temperature of the user and the room temperature is excessive when the user is indoors. The indoor state determination unit 23 reads and uses the sixth threshold value stored in advance in the storage unit 26. Note that the sixth threshold value may be stored in a storage unit included in the indoor state determination unit 23.

  The case where the user is in the floor corresponds to the case where the user is awake but inactive. Therefore, in order not to significantly change the user's surface temperature, a threshold value of a temperature difference between the user's surface temperature and the room temperature in a state that may significantly change the user's surface temperature is set and stored in advance. Then, by comparing this threshold value with the absolute value of the temperature difference between the user's surface temperature and the room temperature, it is possible to determine whether or not the user's surface temperature is likely to change significantly. Become.

  Therefore, when the absolute value of the temperature difference between the user's surface temperature and the room temperature is greater than the sixth threshold, there is a possibility that the user's surface temperature may change significantly, that is, the user's surface temperature and the room temperature. If it is determined that the temperature difference from the temperature is excessive, and the absolute value of the temperature difference between the user's surface temperature and the room temperature is equal to or less than the sixth threshold, the user's surface temperature may be significantly changed. In other words, it is determined that the temperature difference between the surface temperature of the user and the room temperature is not excessive.

  When the absolute value of the temperature difference between the user's surface temperature and the room temperature is equal to or smaller than the sixth threshold value, that is, in the case of No in step S96, the temperature setting process of the series of air conditioning control ends.

  On the other hand, if the absolute value of the temperature difference between the user's surface temperature and the room temperature is greater than the sixth threshold value, that is, if Yes in step S96, the indoor state determination unit 23 in step S97 Temperature difference excess information to the effect that the temperature difference between the room temperature and the room temperature is large is transmitted to the information processing unit 24. When the information processing unit 24 receives the excessive temperature difference information, the information processing unit 24 reduces the temperature difference between the surface temperature of the user and the indoor temperature based on the excessive temperature difference information and the current air conditioning set temperature. Determine the set temperature of the air conditioning. The information processing unit 24 acquires the current setting temperature of air conditioning from the storage unit 26 and uses it. For example, when the user's surface temperature is 24 ° C. and the room temperature is 30 ° C., and the absolute value of the temperature difference between the user's surface temperature and the room temperature is greater than the sixth threshold, The set temperature of the air conditioner in the air conditioner 10 is lowered so as to reduce the temperature difference of the air conditioner.

  After the information processing unit 24 determines the air conditioning control temperature setting of the air conditioner 10 according to the user's state as described above, the information processing unit 24 displays the determined air conditioning setting temperature information as the air conditioning state control unit. 25. The air conditioning state control unit 25 changes the temperature setting of the air conditioning control in the storage unit 26 based on the received information on the set temperature of the air conditioning, controls the compressor of the outdoor unit 12 according to the changed set temperature, and the air conditioner The air conditioning control at 10 is performed. The change period of the temperature setting in the storage unit 26 is stored in advance in the storage unit 26.

  By performing such control, it is possible for the user to perform comfortable air-conditioning control that is kind to the user of the user in the floor.

  Next, the temperature setting process of the air conditioning control when the user is leaving the room in the air conditioner 10 will be described. FIG. 13: is a flowchart which shows the procedure of the temperature setting process of air-conditioning control in case the user is getting out of the room indoors in the air conditioner 10 concerning Embodiment 1 of this invention.

  First, the indoor state determination unit 23 executes the presence determination process illustrated in FIG. 8 as the presence determination process in step S101, and determines in step S102 that the user is out of bed. If it is determined in step S102 that the user is getting out of the room, it can be determined that the user is active and there is no need to change the temperature setting of the air conditioning control. The control process is terminated. In this case, the temperature setting for the air conditioning control is set to the temperature state input from the remote controller 14 to the information processing unit 24 via the receiving unit (not shown), and control for changing the temperature setting for the air conditioning control is not performed. Accordingly, the information processing unit 24 does not determine a new set temperature.

  By performing such control, it is possible to eliminate unnecessary temperature adjustment of air conditioning, and it is possible to perform comfortable air conditioning control that is gentle to the user's body while getting out of bed.

  Next, temperature setting processing of air conditioning control when the user is sleeping in the room of the air conditioner 10 and there is little physical movement will be described. FIG. 14 is a flowchart illustrating a procedure of the temperature setting process of the air conditioning control when the user is sleeping and there is little body movement in the air conditioner 10 according to the first embodiment of the present invention.

  First, the indoor state determination unit 23 performs the presence determination process, the user's breathing determination process, the user's sleep determination process, and the presence determination process described above, and then the comfort shown in FIG. 9 as the comfortable sleep determination process in step S111. The sleep determination process is performed, and it is determined in step S112 that the user's body movement is small.

  Next, the indoor state determination unit 23 receives information on the surface temperature of the room from the surface temperature sensor 21 in step S113, and acquires information on the surface temperature of the user from the information. Next, the indoor state determination unit 23 receives and acquires information on the indoor temperature from the indoor temperature sensor 16 in step S114. Then, in step S115, the indoor state determination unit 23 compares the absolute value of the temperature difference between the user's surface temperature and the room temperature with the seventh threshold value, and calculates the temperature difference between the user's surface temperature and the room temperature. In step S116, it is determined whether the absolute value is larger than the seventh threshold. Note that instead of the information on the indoor surface temperature in step S113, it is also possible to use the information on the indoor surface temperature acquired in the presence determination process.

  The seventh threshold value of the temperature difference is a reference value for determining whether or not the user is sleeping comfortably with little turning of the user when the user is sleeping and there is little body movement. The indoor state determination unit 23 reads out and uses the seventh threshold value stored in advance in the storage unit 26. The seventh threshold value for the temperature difference may be stored in a storage unit provided in the indoor state determination unit 23.

  The fact that the user's body movement is small corresponds to that the user is sleeping comfortably with little turning. Therefore, when the user's body movement is small, a threshold value of a temperature difference between the user's surface temperature and the room temperature in a state where the user is sleeping comfortably with little sleep is preset and stored. . Then, by comparing this threshold value with the absolute value of the temperature difference between the user's surface temperature and the room temperature, it is possible to determine whether the user is sleeping comfortably with less risk of turning over. .

  Therefore, when the absolute value of the temperature difference between the user's surface temperature and the room temperature is greater than the seventh threshold, the user is less likely to turn over and is not comfortably sleeping, i.e., the user's surface temperature. It is determined that the state is likely to change significantly, and when the absolute value of the temperature difference between the user's surface temperature and the room temperature is less than the seventh threshold, the user is less likely to turn over and sleeps comfortably It is determined that the state is in the middle.

  If the absolute value of the temperature difference between the user's surface temperature and the room temperature is equal to or smaller than the seventh threshold value, that is, if No in step S116, the series of air conditioning control temperature setting processing ends.

  On the other hand, if the absolute value of the temperature difference between the user's surface temperature and the room temperature is greater than the seventh threshold, that is, if Yes in step S116, the room state determination unit 23 obtains the temperature maintenance information in step S117. It transmits to the information processing part 24. When the information processing unit 24 receives the temperature maintenance information, the information processing unit 24 determines the air conditioning set temperature based on the temperature maintenance information and the current air conditioning set temperature so as not to significantly change the surface temperature of the user. That is, the information processing unit 24 determines the set temperature of the air conditioning as the current set temperature so as to maintain the user's surface temperature without raising it. The information processing unit 24 acquires the current setting temperature of air conditioning from the storage unit 26 and uses it. In addition, in order to lead the user to a sleep state comfortably, it is also possible to set the set temperature to a set temperature lower than the set temperature of the current air conditioning.

  After the information processing unit 24 determines the air conditioning control temperature setting of the air conditioner 10 according to the user's state as described above, the information processing unit 24 displays the determined air conditioning setting temperature information as the air conditioning state control unit. 25. The air conditioning state control unit 25 changes the temperature setting of the air conditioning control in the storage unit 26 based on the received information on the set temperature of the air conditioning, controls the compressor of the outdoor unit 12 according to the changed set temperature, and the air conditioner The air conditioning control at 10 is performed. The change period of the temperature setting in the storage unit 26 is stored in advance in the storage unit 26.

  By performing such control, it is possible to perform air conditioning control which is user-friendly and can sleep the user comfortably.

  Next, the temperature setting process of the air conditioning control in the air conditioner 10 when the user is sleeping indoors and there are many body movements will be described. FIG. 15 is a flowchart illustrating the procedure of the temperature setting process of the air conditioning control in the air conditioner 10 according to the first embodiment of the present invention when the user is sleeping indoors and there is a lot of body movement.

  First, the indoor state determination unit 23 performs the presence determination process, the user breath determination process, the user sleep determination process, and the bed determination process described above, and then the comfort shown in FIG. 9 as the comfortable sleep determination process in step S121. The sleep determination process is performed, and it is determined in step S122 that the user's body movement is large.

  Next, the indoor state determination unit 23 receives the information on the indoor surface temperature from the surface temperature sensor 21 in step S123, and acquires the information on the user's surface temperature from among the information. Next, the indoor state determination unit 23 receives and acquires information on the indoor temperature from the indoor temperature sensor 16 in step S124. In step S125, the indoor state determination unit 23 compares the absolute value of the temperature difference between the user's surface temperature and the room temperature with the eighth threshold value, and compares the current user's surface temperature with the room temperature. In step S126, it is determined whether the absolute value of the difference is larger than the eighth threshold value of the temperature difference. In addition, it is also possible to use the indoor surface temperature information acquired in the presence determination process instead of the indoor surface temperature information in step S123.

  The eighth threshold value of the temperature difference is a reference value for determining whether or not the user often falls asleep when the user is sleeping and the user has a lot of body movements, and is not comfortable sleeping. is there. The indoor state determination unit 23 reads and uses the eighth threshold value of the temperature difference stored in advance in the storage unit 26. The eighth threshold value of the temperature difference may be stored in the storage unit provided in the interior state determination unit 23.

  The fact that the user is sleeping and has a lot of body movement often turns over and corresponds to being uncomfortable sleeping. In other words, it is considered to be equivalent to the case where it is hot and uncomfortable. In other words, a state in which the user has a lot of body movement during sleep may be a case where the user has a low sleep, but the user may feel hot because the ambient temperature is high. That is, it can be considered that the user's sleep state is a non-comfortable sleep state. That is, the user's body movement increases during uncomfortable sleep. Therefore, when the user's body movement is large, the threshold value of the temperature difference between the user's surface temperature and the room temperature considered to be in the non-comfortable sleep state is set and stored in advance. Then, by comparing this threshold value with the absolute value of the temperature difference between the surface temperature of the user and the room temperature, it is possible to determine whether the user is in a non-comfortable sleep state.

  Therefore, when the absolute value of the temperature difference between the surface temperature of the user and the room temperature is larger than the eighth threshold, it is determined that the user's sleep state is a non-comfortable sleep state, and the user's surface temperature and room When the absolute value of the temperature difference from the temperature is equal to or less than the eighth threshold, it is determined that the user's sleep state is not an uncomfortable sleep state.

  When the absolute value of the temperature difference between the surface temperature of the user and the room temperature is equal to or less than the eighth threshold value, that is, No in step S126, the series of air conditioning control processing ends.

  On the other hand, if the absolute value of the temperature difference between the surface temperature of the user and the room temperature is larger than the eighth threshold, that is, Yes in step S126, the room condition determination unit 23 in step S127 Is transmitted to the information processing unit 24. Then, when the temperature difference excess information is received, the information processing unit 24 determines the setting temperature of the air conditioning so that the surface temperature of the user is lowered based on the temperature difference excess information and the current setting temperature of the air conditioning. That is, the information processing unit 24 determines the set temperature of the air conditioning lower than the current set temperature of the air conditioning. The information processing unit 24 acquires the current setting temperature of air conditioning from the storage unit 26 and uses it.

  After the information processing unit 24 determines the air conditioning control temperature setting of the air conditioner 10 according to the user's state as described above, the information processing unit 24 displays the determined air conditioning setting temperature information as the air conditioning state control unit. 25. The air conditioning state control unit 25 changes the temperature setting of the air conditioning control in the storage unit 26 based on the received information on the set temperature of the air conditioning, controls the compressor of the outdoor unit 12 according to the changed set temperature, and the air conditioner The air conditioning control at 10 is performed. The change period of the temperature setting in the storage unit 26 is stored in advance in the storage unit 26.

  By performing such control, it is possible to reduce the body movement of the user during sleep and to perform air conditioning control that allows the user to sleep comfortably.

  As described above, the air conditioner 10 according to the first embodiment confirms the presence or absence of a user in the room with the flow shown in FIG. 4 or FIG. When the user exists in the room, the air conditioner 10 can determine the user's state according to the flow shown in FIGS. 6 to 9. The state of the user that can be determined by the air conditioner 10 is as follows. (1) Whether the user is breathing or apnea. (2) Whether the user is awake or sleeping. (3) If the user is awake, is the user in bed or out of bed? (4) If the user is sleeping, is the user in a state where there is a lot of body movement or in a state where there is little body movement? Then, the air conditioner 10 can change the temperature setting of the air conditioner 10 according to the flow illustrated in FIGS. 10 to 15 based on the determination result of the state of the user.

  As described above, the air conditioner 10 according to the first embodiment checks both the information on the indoor surface temperature detected by the surface temperature sensor 21 and the frequency difference information detected by the radio wave sensor 22. This makes it possible to more reliably determine the presence of the user in the room, and improves the reliability. Further, even when the detection sensitivity of one of the surface temperature sensor 21 and the radio wave sensor 22 is lowered, it is possible to determine that the user exists in the room.

  Moreover, the air conditioner 10 concerning this Embodiment 1 can provide the setting of the comfortable air-conditioning control according to the user's state. Also, the air conditioner 10 needs part of the flow for determining the state of the user shown in FIGS. 6 to 9 and the flow for setting the temperature of the air conditioner 10 shown in FIGS. 10 to 15. It is also possible to simplify the control process of the air conditioner 10 by omitting accordingly.

  Even if the technology of Patent Document 1 and the technology of Patent Document 2 are simply combined, the output from the infrared sensor and the output from the Doppler sensor will be used alone. On the other hand, the air conditioner 10 according to the first embodiment can detect the state of the user using the outputs of both the surface temperature sensor 21 and the radio wave sensor 22. Thereby, the air conditioner 10 concerning this Embodiment 1 can determine a user's state more reliably, and determination with high reliability is possible. In addition, the air conditioner 10 can perform air-conditioning control using not only the presence / absence of the user in the room but also the detailed information of the user such as whether the user is breathing or whether the user is sleeping. . Thus, the air conditioner 10 according to the first embodiment can automatically perform air conditioning control that is comfortable for the user.

  Therefore, the air conditioner 10 according to the first embodiment of the present invention can reliably detect the state of the user, and can perform comfortable air conditioning control for the user according to the state of the user.

Second Embodiment
In the above-described first embodiment, the case where the temperature setting of the indoor unit 11 is changed according to the state of the user in the room has been described. However, in the second embodiment, the indoor environment information in which air conditioning is performed by the air conditioner An air conditioner system capable of providing an external user with the user's state and temperature setting is described.

  FIG. 16: is a block diagram which shows the main functional structures of the air conditioning system concerning Embodiment 2 of this invention. FIG. 17 is a block diagram illustrating a main functional configuration of the air conditioner 30 according to the second embodiment of the present invention. In FIG. 17, about the same structure as the air conditioner 10 shown in FIG. 2, the same code | symbol as FIG. 2 is described.

  The air conditioning system according to the second embodiment includes an air conditioner 30, an external server 40, and an external information terminal 50.

  The air conditioner 30 according to the second embodiment is different from the air conditioner 10 according to the first embodiment in having a communication unit 31. The air conditioner 30 includes the communication unit 31 and can communicate with the external server 40. The communication unit 31 is indoor environment information, for example, indoor user state information, indoor presence, absence, breathing, apnea, awakening, sleep, in bed, getting out of bed, body movement, body movement is small , And settings of the air conditioner 30 are transmitted to the external information terminal 50 via the external server 40 using a network technology such as the Internet. The communication unit 31 is controlled by the air conditioning state control unit 25.

  The communication unit 31 includes one or a plurality of microcomputers. That is, the communication unit 31 is realized, for example, as a processing circuit of the hardware configuration shown in FIG. The communication unit 31 is realized, for example, by the processor 101 illustrated in FIG. 3 executing a program stored in the memory 102. Also, a plurality of processors and a plurality of memories may cooperate to realize the function of the communication unit 31. A part of the functions of the communication unit 31 may be mounted as an electronic circuit, and the other part may be realized using the processor 101 and the memory 102. The processor and the memory for realizing the communication unit 31 may be the same as the processor and the memory for realizing one or more of the indoor state determination unit 23, the information processing unit 24, and the air conditioning state control unit 25. It may be another processor and memory.

  The external server 40 can communicate with the air conditioner 30 and the external information terminal 50. The external server 40 is not particularly limited as long as it is a server having a communication unit capable of communicating with the air conditioner 30 and the external information terminal 50.

  The external information terminal 50 can communicate with the external server 40 and can communicate with the air conditioner 30 via the external server 40. The external information terminal 50 is not particularly limited as long as it is a server having a communication unit capable of communicating with the external server 40.

  Next, the operation of the communication unit 31 will be described. In the processing described in the first embodiment, various types of information about indoor users, that is, presence, absence, breathing, apnea, awakening, sleep, bed presence, getting out of bed, body movement, and body movement are small. This information can be acquired without taking a picture of the user with a photographing device such as a CCD camera, and therefore privacy infringement is considered. By transmitting these pieces of information to the external information terminal 50 through the communication unit 31, it is possible for other users having the external information terminal 50 to check information on users in the room where the air conditioner 30 is installed. is there.

  As a result, the air conditioning system according to the second embodiment detects the living situation and the living situation of a person with little communication with the surroundings, such as an elderly person living alone, using only an air conditioner that is frequently used in daily life. be able to. The air conditioning system according to the second embodiment can also be used to confirm the existence or survival of residents in a place where a group life such as a nursing home or a dormitory operates. Therefore, by using the air conditioning system according to the second embodiment, it is possible to construct a user monitoring system using an air conditioner. Then, by linking with another external service, it becomes possible to make an emergency response such as another user rushing immediately if the user is not breathing.

  As described above, the air-conditioning system according to the second embodiment is configured so that the state of the user in the room and the control state of the air conditioner 30 in accordance with the state without using a device that may infringe the privacy of the user. It can be transmitted from the communication unit 31 to the external information terminal 50 through the external server 40. Thereby, the user's detailed situation such as whether the air conditioner 30 is used but breathing and the control state of the air conditioner 30 can be provided to an external user without infringing on the privacy. It is possible for external users to acquire information related to safety, such as the existence of

  The configuration shown in the above embodiment shows an example of the contents of the present invention, and can be combined with another known technique, and one of the configurations is possible within the scope of the present invention. Parts can be omitted or changed.

  10, 30 air conditioners, 11 indoor units, 12 outdoor units, 13 refrigerant pipes, 14 remote controllers, 15 outdoor temperature sensors, 16 indoor temperature sensors, 17 indoor unit switches, 21 surface temperature sensors, 22 radio wave sensors, 23 indoor conditions Judgment unit, 24 information processing unit, 25 air conditioning state control unit, 26 storage unit, 31 communication unit, 40 external server, 50 external information terminal, 101 processor, 102 memory.

Claims (15)

An air conditioner comprising: an indoor unit; an outdoor unit connected to the indoor unit; and a remote controller that transmits a control instruction command for the air conditioner to the indoor unit,
The indoor unit is
A surface temperature sensor for detecting a surface temperature of a room which is a space to be air conditioned;
A radio wave sensor that transmits radio waves of transmission waves into the room, detects radio waves of reflection waves reflected by an object, and detects a difference in frequency between the transmission waves and the reflection waves;
Uniformity of the distribution of the surface temperature in the room based on the detection result in the surface temperature sensor, and the distribution of the difference in frequency between the transmitted wave and the reflected wave in the room based on the detection result in the radio wave sensor. A first presence determination process for determining whether or not the user exists in the room based on both the characteristics and the user in the room based on at least the uniformity of the surface temperature distribution in the room An indoor state determination unit which performs a second presence determination process of determining whether the user exists, and further determines the state of the user in the room based on the detection result of the radio wave sensor;
An information processing unit that determines a control setting condition of the air conditioner according to the state of the user in the room based on the determination result of the state of the user in the room in the room state determination unit;
An air-conditioning state control unit that controls the air conditioner based on a control setting condition of the air conditioner determined by the information processing unit;
Equipped with a,
The indoor state determination unit
It is possible to switch between the first presence determination process and the second presence determination process,
In the first existence determination process,
The user exists in the room when the uniformity of the distribution of the surface temperature of the room and the uniformity of the distribution of the frequency difference between the transmitted wave and the reflected wave are not uniform throughout the room. It is judged that
When the uniformity of the distribution of the surface temperature of the room and the uniformity of the distribution of the frequency difference between the transmitted wave and the reflected wave are both uniform throughout the room, the user can enter the room. Determined to be absent,
In the second existence determination process,
When the uniformity of the surface temperature distribution in the room is uniform throughout the room, it is determined that the user is absent in the room,
The user exists in the room when the uniformity of the distribution of the surface temperature of the room and the uniformity of the distribution of the frequency difference between the transmitted wave and the reflected wave are not uniform throughout the room. It is judged that
When the uniformity of the distribution of the surface temperature of the room is not uniform throughout the room, and the uniformity of the distribution of the frequency difference from the reflected wave is uniform throughout the room, Determining that the user is absent from the room;
Air conditioner characterized by. The indoor state determination unit, after determining that there is a user in the room, obtains a detection result in the radio wave sensor and a reference value stored in the indoor unit in advance for determining the state of the user in the room. Determining the state of the user in the room by comparing;
The air conditioner according to claim 1 . The indoor state determination unit determines whether or not the user in the room is breathing by comparing the detection result of the radio wave sensor with the first threshold value which is the reference value after determining that the user exists in the room. To determine
The air conditioner according to claim 2 . After the indoor state determination unit determines that the user in the room is breathing, the indoor user is awakened by comparing the detection result of the radio wave sensor with the second threshold value which is the reference value. To determine whether or not
The air conditioner according to claim 3 . After determining that the user in the room is awake, the indoor state determination unit compares the detection result of the radio wave sensor with the third threshold value that is the reference value, so that the user in the room is in bed. To determine whether or not
The air conditioner according to claim 4 . The indoor state determination unit, after determining that the user in the room is sleeping, compares the detection result of the radio wave sensor with the fourth threshold value which is the reference value, thereby moving the body movement of the user in the room. Determining whether or not there is more than the reference value for determining whether or not a comfortable sleep state;
The air conditioner according to claim 4 . The indoor unit includes an indoor temperature sensor that detects an indoor temperature of the room;
The outdoor unit includes an outside temperature sensor for detecting outside temperature,
When the indoor state determination unit determines that the user is absent from the room, the information processing unit converts the indoor temperature detected by the indoor temperature sensor to the outdoor temperature detected by the outdoor temperature sensor. Determining the set temperature of the control setting to approach,
The air conditioner according to claim 1 . The information processing unit determines control information for ending the operation of air conditioning of the air conditioner when the indoor state determination unit determines that the user is not present in the room.
The air conditioner according to claim 1 . The indoor unit includes an indoor temperature sensor that detects an indoor temperature of the room;
When the indoor state determination unit determines that the user is present in the room, the information processing unit detects the surface temperature of the user detected by the surface temperature sensor and the indoor temperature sensor. Determining the set temperature of the control setting to reduce the difference with the indoor temperature;
The air conditioner according to claim 1 . When the information processing unit determines that the indoor state determination unit determines that the user has left the floor in the room, the information processing unit does not determine a new set temperature for the control setting.
The air conditioner according to claim 1 . When the indoor state determination unit determines that the user is sleeping in the room with little body movement, the information processing unit determines the set temperature of the control setting as the current set temperature of the control setting. To do,
The air conditioner according to claim 1 . When the indoor state determination unit determines that the user is sleeping in the room with a lot of body movement, the information processing unit sets the set temperature of the control setting to be higher than the set temperature of the current control setting. To determine the low temperature,
The air conditioner according to claim 1 . Providing a storage unit for storing control information of the air conditioner in the air conditioning state control unit;
The air conditioner according to any one of claims 1 to 12 , characterized in that Providing a communication unit that transmits information on the determination result of the information processing unit to an external server;
The air conditioner according to claim 1. An air conditioner according to claim 14 ,
An external server capable of communicating with the air conditioner;
An external information terminal capable of communicating with the external server;
An air conditioning system comprising:

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