JP2012042096A - Physiological function activating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve an activating action of a physiological function in a physiological function activating device.SOLUTION: In temperature fluctuation operation, both high-temperature holding motion and low-temperature holding motion are alternately performed at least once by once. When the high-temperature holding motion is performed, the target temperature of a room air conditioner (20) is retained at the target temperature on the high-temperature side to give thermal stimulation to a human body. On the other hand, when the low-temperature holding motion is performed, the target temperature of the room air conditioner (20) is retained at the target temperature on the low-temperature side to give low-heat stimulation to the human body. Moreover, the angle of the flap (34) of the room air conditioner (20) is changed so that the air in the room is dehumidified by an indoor heat exchanger (25) during the low-temperature holding motion and on the other hand the air humidified by a humidification nozzle (61) directly reaches the human body from a blowout port (33) during the high-temperature holding motion.

Description

  The present invention relates to a physiological function activation device that activates physiological functions of a human body by applying thermal stimulation and cold stimulation to the human body.

  As a physiological function activating device for activating a physiological function of the human body (particularly a peripheral blood vessel driving function or the like), a device that imparts a thermal stimulus and a cold stimulus to the human body is known. Patent Document 1 discloses this type of physiological function activation device.

  The physiological function activation device of Patent Document 1 includes a heat pump type air conditioner and a control unit for controlling the air conditioner. In this air conditioner, in addition to a normal cooling operation and a heating operation, a temperature fluctuation operation (fluctuation operation mode) is performed in which a room temperature is changed to give a thermal stimulus or a cold stimulus to the occupant. By this temperature fluctuation operation, the peripheral vasomotor function of the human body is activated, and as a result, blood pressure regulating action, blood circulation regulating action, body temperature regulating action and the like are promoted.

JP 2009-41795 A

  By the way, in the physiological function activation device disclosed in Patent Document 1, when the low temperature holding operation is executed, the temperature around the human body is lowered, and a cold stimulus is applied to the human body. As a result, the peripheral blood vessels of the human body contract. Here, during the low-temperature holding operation, the humidity tends to be relatively high, and when the humidity is high, the amount of heat released by perspiration decreases, while the amount of heat released by blood flow increases and the peripheral blood vessels of the skin expand.

  In addition, when the high temperature holding operation is executed, the temperature around the human body becomes high and thermal stimulation is applied to the human body. As a result, the peripheral blood vessels of the human body are expanded. Here, during the high temperature holding operation, the humidity tends to be relatively low, and when the humidity is low, the amount of heat released by perspiration increases, while the amount of heat released by blood flow decreases and the skin peripheral blood vessels contract.

  As described above, the humidity change around the human body acts in a phase opposite to the temperature change, that is, the effect of contraction and expansion of the peripheral blood vessels of the skin is reduced, so that the physiological function is effectively activated. It is not preferable.

  This invention is made | formed in view of this point, The objective is to improve the activation effect | action of a physiological function in a physiological function activation apparatus.

  The present invention is directed to a physiological function activation device and has taken the following solutions.

That is, the first invention is an air conditioning unit (20) that changes the temperature in the room in order to give a thermal stimulus and a cool stimulus to the human body,
A high temperature holding operation in which the target temperature of the air conditioning unit (20) is held at a high temperature side target temperature for applying the thermal stimulus over a predetermined time, and the target temperature of the air conditioning unit (20) is over a predetermined time. An air-conditioning control unit (50) for performing a temperature fluctuation operation in which a low-temperature holding operation that is lower than a high-temperature side target temperature and held at a low-temperature side target temperature for applying the cold energy stimulus is executed at least once;
And a dehumidifying section (25) for dehumidifying the indoor air during the low temperature holding operation.

  Here, the “high temperature side target temperature” is a target temperature for giving a desired thermal stimulus to the human body among the temperatures of air in the vicinity of the human body. Further, the “low temperature side target temperature” here is a target temperature for giving a desired cold stimulus to the human body among the temperatures of the air in the vicinity of the human body.

  In the first invention, the high temperature side target temperature and the low temperature side target temperature are set, and in the temperature fluctuation operation, the high temperature holding operation and the low temperature holding operation are alternately performed at least once. When the high temperature holding operation is executed, the target temperature of the air conditioning unit (20) is held at the high temperature side target temperature. Thereby, the temperature around the human body is increased and thermal stimulation is applied to the human body. As a result, for example, the peripheral blood vessels of the human body are expanded. On the other hand, when the low temperature holding operation is executed, the target temperature of the air conditioning unit (20) is held at the low temperature side target temperature. Thereby, the temperature around the human body is lowered, and a cold stimulus is applied to the human body. As a result, for example, the peripheral blood vessels of the human body contract. As described above, in the temperature fluctuation operation, the high-temperature holding operation and the low-temperature holding operation are alternately performed at least once, so that the thermal stimulus and the cold stimulus are applied to the human body.

  Furthermore, the indoor air is dehumidified by the dehumidifying section (25) during the low temperature holding operation. In this way, when applying a cold stimulus to the human body, the temperature difference on the cold stimulus side is increased by reducing the humidity in the vicinity of the human body even when the same temperature change is given to the human body. And the effect of contraction of peripheral skin blood vessels is increased.

The second aspect of the invention is an air conditioning unit (20) that changes a room temperature in order to give a thermal stimulus and a cold stimulus to a human body,
A high temperature holding operation in which the target temperature of the air conditioning unit (20) is held at a high temperature side target temperature for applying the thermal stimulus over a predetermined time, and the target temperature of the air conditioning unit (20) is over a predetermined time. An air-conditioning control unit (50) for performing a temperature fluctuation operation in which a low-temperature holding operation that is lower than a high-temperature side target temperature and held at a low-temperature side target temperature for applying the cold energy stimulus is executed at least once;
And a humidifying section (61) for humidifying the air in the room during the high temperature holding operation.

  In the second invention, the indoor air is humidified by the humidifying section (61) during the high temperature holding operation. In this way, when applying thermal stimulation to the human body, increasing the humidity near the human body increases the temperature difference on the thermal stimulation side even when the same temperature change is applied to the human body. This can increase the effect of expanding the peripheral blood vessels of the skin.

According to a third invention, in the second invention,
A dehumidifying section (25) for dehumidifying the indoor air during the low temperature holding operation is provided.

  In the third aspect of the invention, the room air is dehumidified by the dehumidifying unit (25) during the low temperature holding operation, while the room air is humidified by the humidifying unit (61) during the high temperature holding operation. In this way, when applying a cold stimulus to the human body, while reducing the humidity near the human body, while increasing the humidity near the human body when applying a thermal stimulus, the same temperature change is applied to the human body. Even if it is provided, the temperature difference between the cold stimulation side and the thermal stimulation side can be increased, and the effect of contraction and expansion of the peripheral skin blood vessels is increased.

4th invention is 2nd or 3rd invention,
The air-conditioning unit (20) is controlled so as to allow the air humidified by the humidifying unit (61) to reach the human body directly from the air outlet (33) during the high-temperature holding operation. It is a feature.

  In the fourth invention, in the air conditioning unit (20), during the high temperature holding operation, the air blowing operation is controlled so that the air humidified by the humidifying unit (61) directly reaches the human body from the blower outlet (33). . In this way, the humidity of the air in the vicinity of the human body can be effectively increased.

A fifth invention is the fourth invention,
The air outlet (33) is provided with a flap (34) capable of changing the air direction of the air,
The flap angle of the flap (34) is changed so that the air humidified by the humidifying unit (61) can reach the human body directly from the air outlet (33) during the high temperature holding operation. It is a feature.

  In 5th invention, a flap (34) is provided in the blower outlet (33) of an air-conditioning part (20). Then, during the high temperature holding operation, the flap angle is changed so that the air humidified by the humidifying section (61) reaches the human body directly from the air outlet (33). In this way, it is possible to control the humidified air to reach the human body directly by changing the angle of the flap (34).

  According to the present invention, since the temperature around the human body can be rapidly increased or decreased in the temperature fluctuation operation, it is possible to apply a cold stimulus or a hot stimulus to the human body. As a result, for example, the function of the peripheral blood vessels of the skin can be activated, and the physiological function of the human body can be effectively activated. Therefore, it can promote blood pressure regulating action, blood circulation regulating action, body temperature regulating action, etc. of the human body, thereby improving coldness, preventing hypertension, preventing metabolism / repair function from being lowered, promoting fatigue recovery, heat stroke prevention, etc. Can be achieved.

  Furthermore, the indoor air is dehumidified by the dehumidifying section (25) during the low temperature holding operation. In this way, when applying a cold stimulus to the human body, the temperature difference on the cold stimulus side is increased by reducing the humidity in the vicinity of the human body even when the same temperature change is given to the human body. And the effect of contraction of peripheral skin blood vessels is increased.

  Further, during the high temperature holding operation, the indoor air is humidified by the humidifying section (61). In this way, when applying thermal stimulation to the human body, increasing the humidity near the human body increases the temperature difference on the thermal stimulation side even when the same temperature change is applied to the human body. This can increase the effect of expanding the peripheral blood vessels of the skin.

It is a schematic block diagram showing the driving | running state of the physiological function activation apparatus which concerns on embodiment of this invention. It is a schematic block diagram of the refrigerant circuit of a room air conditioner. It is a block diagram which shows schematic structure of a physiological function activation apparatus. It is a time chart figure showing change of target temperature of a physiological function activating device. It is a graph showing the change of fingertip skin temperature. It is an example of a temperature fluctuation pattern, and is a time chart showing the change of the target temperature of the physiological function activating device. It is a graph showing the relationship between the distance between a room air conditioner and a human body, and the temperature and speed of the airflow reaching the human body. It is a time chart showing the change of the target temperature when the temperature variation pattern is fixed.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature and is not intended to limit the present invention, its application, or its use.

  FIG. 1 is a schematic configuration diagram illustrating an operation state of the physiological function activation device according to the embodiment of the present invention. As shown in FIG. 1, the physiological function activating device (10) activates the physiological function of the human body by giving a thermal stimulus and a cold stimulus to the human body. ).

  The room air conditioner (20) constitutes a heat pump refrigeration apparatus (air conditioner) that performs a vapor compression refrigeration cycle. That is, the room air conditioner (20) includes a refrigerant circuit (21) that performs a refrigeration cycle by circulating refrigerant (see FIG. 2). A compressor (22), an outdoor heat exchanger (23), an expansion valve (24), an indoor heat exchanger (25), and a four-way switching valve (26) are connected to the refrigerant circuit (21). ing. The compressor (22) is configured as an inverter type having a variable capacity. The expansion valve (24) is composed of, for example, an electronic expansion valve.

  In the refrigerant circuit (21), the flow path of the refrigerant is changed as the four-way switching valve (26) is switched. Thereby, in the refrigerant circuit (21), a refrigeration cycle in which the outdoor heat exchanger (23) serves as a condenser and the indoor heat exchanger (25) serves as an evaporator (refrigeration cycle in which the refrigerant flows in the direction of the solid line arrow in FIG. 2). And a refrigeration cycle (a refrigeration cycle in which the refrigerant flows in the direction of the broken line arrow in FIG. 2) in which the outdoor heat exchanger (23) serves as an evaporator and the indoor heat exchanger (25) serves as a condenser can be changed. .

  The room air conditioner (20) includes an indoor unit (30) disposed in the indoor space (S). The indoor unit (30) is configured, for example, as a so-called wall-mounted type that is attached to an indoor wall surface.

  The indoor unit (30) includes a horizontally long casing (31). In the casing (31), a suction port (32) is formed on the front side, and an air outlet (33) is formed in the lower part. An air passage is formed in the casing (31) from the inlet (32) to the outlet (33). The air passage is provided with the indoor heat exchanger (25) and the indoor fan (27) described above.

  A drain pan (36) is provided below the indoor heat exchanger (25). The drain pan (36) is formed of a flat container open at the top. The drain pan (36) collects moisture condensed in the air when the air is cooled by the indoor heat exchanger (25). Thus, the indoor heat exchanger (25) constitutes a dehumidifying unit that dehumidifies moisture in the air.

  When the indoor fan (27) is operated, the air in the indoor space (S) is taken into the casing (31) through the suction port (32). After passing through the indoor heat exchanger (25), this air is supplied to the indoor space (S) through the air outlet (33). The indoor fan (27) constitutes an air blowing unit that supplies air to the human body. Further, the indoor fan (27) is configured such that the rotational speed of the fan motor is variable. The air outlet (33) is provided with a flap (34) as an airflow control plate and a humidifying nozzle (61) as a humidifying unit for humidifying air. By controlling the angle of the flap (34), the wind direction of the blown air can be changed.

  The indoor unit (30) is connected to the outdoor unit (60) through a communication pipe (21a) through which the refrigerant flows. The outdoor unit (60) includes a rectangular outdoor casing (62). In the outdoor casing (62), a compressor (22), an outdoor heat exchanger (23), an outdoor fan (not shown), and the like are provided. The outdoor casing (62) is provided with an adsorption rotor (63), a heater (64), a cooler (65), and a humidified water tank (66).

  The adsorption rotor (63) is formed in a flat cylindrical shape, and a rotation shaft is inserted through the axis of the suction rotor (63). An adsorbent for adsorbing moisture is supported on the surface of the adsorption rotor (63). On the other hand, in the outdoor casing (62), an adsorption passage (62a) and a regeneration passage (62b) through which outdoor air flows are defined. The adsorption rotor (63) is configured to be rotatable over the adsorption passage (62a) and the regeneration passage (62b). In the adsorption rotor (63), an adsorption zone (63a) is formed in a region facing the adsorption passage (62a), and a regeneration zone (63b) is formed in a region facing the regeneration passage (62b).

  In the regeneration passage (62b), a heater (64) is disposed on the upstream side of the outdoor air with respect to the adsorption rotor (63). The heater (64) heats the outdoor air immediately before flowing through the regeneration zone (63b) of the adsorption rotor (63). In the regeneration passage (62b), a cooler (65) is disposed downstream of the outdoor air with respect to the adsorption rotor (63). The cooler (65) cools the outdoor air after passing through the regeneration zone (63b) of the adsorption rotor (63).

  The humidified water tank (66) is installed below the cooler (65). The humidified water tank (66) collects moisture in the air condensed by the cooler (65) and stores this moisture as humidified water. Further, one end of the humidified water supply pipe (67) is connected to the humidified water tank (66). The other end of the humidified water supply pipe (67) is connected to the humidifying nozzle (61) described above. The humidified water supply pipe (67) is provided with a humidified water supply pump (68).

  FIG. 3 is a block diagram showing a schematic configuration of the physiological function activation device. As shown in FIG. 3, the physiological function activating device (10) includes a setting unit (40) and an air conditioning control unit (50).

  Various operating parameters relating to the room air conditioner (20) are set in the setting unit (40). The setting unit (40) includes an operation switching setting unit (41), a normal operation setting unit (42), and a variable operation setting unit (43).

  The operation switching setting unit (41) is a switch for switching the operation of the room air conditioner (20). The operation mode of the room air conditioner (20) is roughly classified into “normal operation” and “forge operation”. The “normal operation” is an operation for performing air conditioning so that the temperature of the indoor space (S) approaches a temperature desired by the user (air conditioning target temperature). This "normal operation" is classified into a cooling operation in which a refrigeration cycle using the indoor heat exchanger (25) as an evaporator and a heating operation in which a refrigeration cycle using the indoor heat exchanger (25) as a condenser are performed. . Further, the “training operation” is an operation for activating the physiological functions of the occupants in the indoor space (S). That is, the “training operation” is a temperature fluctuation operation in which a thermal stimulus and a cold stimulus are given to the human body by changing the temperature of the indoor space (S).

  In the normal operation setting unit (42), operation parameters related to normal operation of the room air conditioner (20) are set. Specifically, the normal operation setting unit (42) includes an air conditioning temperature setting unit (42a), an air volume setting unit (42b), and an air direction setting unit (42c).

  The set temperature Ts in the room to be air-conditioned by the room air conditioner (20) is input to the air conditioning temperature setting unit (42a). That is, the target temperature of the room air conditioner (20) during normal operation is set in the air conditioning temperature setting unit (42a).

  In the air volume setting unit (42b), the air volume of the air blown out from the air outlet (33) is input and set for the room air conditioner (20) during normal operation. Note that the air volume of the blown air can be changed, for example, by controlling the rotational speed of the motor of the indoor fan (27).

  In the wind direction setting unit (42c), the wind direction of the air blown from the room air conditioner (20) during normal operation is input and set. The air direction of the blown air can be changed by controlling the angle of the flap (34) provided at the blower outlet (33).

  In the variable operation setting unit (43), operation parameters related to the training operation of the room air conditioner (20) are set. Specifically, the fluctuating operation setting unit (43) includes a stimulation temperature setting unit (43a) and a fluctuation pattern setting unit (43b).

  In the stimulation temperature setting section (43a), a high temperature side target temperature Tmax and a low temperature side target temperature Tmin are set as target temperatures of the room air conditioner (20) during the training operation. The high temperature side target temperature Tmax is a temperature for applying a thermal stimulus to the human body during the training operation, and is an environmental temperature for dilating the peripheral blood vessels of the human body. That is, the high temperature side target temperature Tmax is a target temperature for giving a desired thermal stimulus to the human body among the temperatures of the air in the vicinity of the human body. In the present embodiment, the high temperature side target temperature Tmax is set to 28 ° C. or more and 32 ° C. or less.

  Further, the low temperature side target temperature Tmin is a temperature for applying a cold stimulus to the human body during the training operation, and is an environmental temperature for contracting the peripheral blood vessels of the human body. That is, the low temperature side target temperature Tmin is a target temperature for giving a desired cooling stimulus to the human body among the temperatures of the air in the vicinity of the human body. In the present embodiment, the low temperature side target temperature Tmin is set to 18 ° C. or more and 22 ° C. or less.

  In the fluctuation pattern setting unit (43b), a fluctuation pattern of the target temperature is set, such as how to change the target temperature of the room air conditioner (20) during the training operation over time. . Specifically, as shown in FIG. 4, the change pattern setting unit (43b) sets the target temperature of the room air conditioner (20) in the order of Tmin → Tmax → Tmin, from the start to the end of the training operation. A variation pattern that changes is set. In other words, in the present embodiment, when the operation of holding the target temperature of the room air conditioner (20) at the low temperature side target temperature Tmin (low temperature holding operation) is completed, the target temperature of the room air conditioner (20) is held at the high temperature side target temperature Tmax. When the high temperature holding operation is completed, the low temperature holding operation is executed again.

  Moreover, the time (t1, t2, t3) when each operation | movement mentioned above is performed is set to the fluctuation pattern setting part (43b) of this embodiment (refer FIG. 4). In the present embodiment, the first time t1 is set to 12.5 minutes, the second time t2 is set to 35 minutes, and the third time t3 is set to 12.5 minutes. In other words, in this embodiment, the time during which the high temperature holding operation is executed (time t2 in this embodiment) is longer than the time during which the low temperature holding operation is executed (time t1 and time t3 in this embodiment). ing. In this embodiment, the execution time of the low temperature holding operation immediately before the high temperature holding operation (time t1 in this embodiment) and the execution time of the low temperature holding operation immediately after the high temperature holding operation (time t3 in this embodiment). ) Is set to the same time (for example, 12.5 minutes).

  The air conditioning control unit (50) controls the room air conditioner (20) based on various operation parameters set in the setting unit (40), and includes a controller for performing normal operation and training operation. It is composed. The air conditioning control unit (50) controls, for example, the operating frequency of the compressor (22), the rotational speed of the indoor fan (27), the opening of the expansion valve (24), the setting of the four-way switching valve (26), etc. It is configured.

-Driving action-
Hereinafter, the operation of the physiological function activation device (10) will be described.

<Normal operation>
First, normal operation of the room air conditioner (20) will be described. In the normal operation of the room air conditioner (20), the cooling operation and the heating operation are switched.

  In cooling operation, four-way switching is performed so that the discharge side of the compressor (22) communicates with the outdoor heat exchanger (23) and at the same time the suction side of the compressor (22) communicates with the indoor heat exchanger (25). Valve (26) is set. When the compressor (22) is operated from this state, the refrigerant discharged from the compressor (22) condenses in the outdoor heat exchanger (23) and is depressurized by the expansion valve (24), and then the indoor heat exchange is performed. Flow through the vessel (25) (see solid arrow in FIG. 2).

  When the indoor fan (27) is operated in the room air conditioner (20) during the cooling operation, the air in the indoor space (S) is introduced into the casing (31) from the suction port (32). The air introduced into the casing (31) flows through the air passage and passes through the indoor heat exchanger (25). At this time, moisture in the air is condensed by the indoor heat exchanger (25), and the condensed moisture is collected in the drain pan (36). As a result, air is dehumidified. In the indoor heat exchanger (25), the refrigerant absorbs heat from the air and evaporates, and the air is cooled. The refrigerant evaporated in the indoor heat exchanger (25) is sucked into the compressor (22) and compressed. The air cooled by the indoor heat exchanger (25) is supplied to the outside of the casing (31) (that is, the indoor space (S)) through the air outlet (33).

  During heating operation, the four-way switching is performed so that the discharge side of the compressor (22) communicates with the indoor heat exchanger (25) and at the same time the suction side of the compressor (22) communicates with the outdoor heat exchanger (23). Valve (26) is set. When the compressor (22) is operated from this state, the refrigerant discharged from the compressor (22) flows through the indoor heat exchanger (25) (see the broken line arrow in FIG. 2).

  Further, when the indoor fan (27) is operated in the room air conditioner (20) during the heating operation, the air in the indoor space (S) is introduced into the casing (31) from the suction port (32). The air introduced into the casing (31) flows through the air passage and passes through the indoor heat exchanger (25). In the indoor heat exchanger (25), the refrigerant dissipates heat into the air and condenses, and the air is heated. The refrigerant condensed in the indoor heat exchanger (25) is depressurized by the expansion valve (24) and then evaporated by the outdoor heat exchanger (23), and is sucked into the compressor (22) and compressed.

  Next, a heating / humidifying operation for performing humidification during the heating operation will be described. First, in the outdoor unit (60), outdoor air is introduced into the adsorption passage (62a) and the regeneration passage (62b), respectively. Further, the suction rotor (63) rotates at a predetermined speed with the rotation axis as an axis.

  The outdoor air flowing through the adsorption passage (62a) passes through the adsorption zone (63a) of the adsorption rotor (63). In the adsorption zone (63a), moisture in the outdoor air is adsorbed by the adsorbent. The outdoor air after passing through the adsorption zone (63a) is discharged to the outside of the outdoor casing (62).

  The outdoor air flowing through the regeneration passage (62b) is heated by the heater (64) and then passes through the regeneration zone (63b) of the adsorption rotor (63). In the regeneration zone (63b), the adsorbent is heated by outdoor air, so that moisture adsorbed on the adsorbent is desorbed. As a result, moisture is imparted to the air flowing through the regeneration zone (63b), while the adsorbent in the regeneration zone (63b) is regenerated.

  The outdoor air that has passed through the regeneration zone (63b) passes through the cooler (65). When the outdoor air is cooled by the cooler (65), moisture in the outdoor air is condensed. The condensed water is collected in the humidified water tank (66). In addition, outdoor air used for supplying moisture to the humidified water tank (66) is discharged to the outside of the outdoor casing (62).

  In this heating / humidifying operation, the humidifying water supply pump (68) is in an operating state. As a result, the humidified water in the humidified water tank (66) is pumped up to the indoor unit (30) via the humidified water supply pipe (67). The humidified water is discharged from the humidifying nozzle (61) into the air. As a result, moisture is imparted to the air flowing in the vicinity of the humidifying nozzle (61).

  As described above, the heated and humidified air is supplied to the outside of the casing (31) (that is, the indoor space (S)) through the air outlet (33).

  In such normal operation (cooling operation or heating operation), the temperature of the indoor space (S) to be air-conditioned by the room air conditioner (20) approaches the set temperature Ts set in the air-conditioning temperature setting unit (42a). In addition, the capacity of the room air conditioner (20) is controlled. Specifically, for example, a suction temperature sensor (35) is provided in the suction port (32) of the room air conditioner (20) of the present embodiment. The air conditioning controller (50) controls the operating frequency and start / stop of the compressor (22) so that the temperature of the air (suction air) detected by the suction temperature sensor (35) approaches the set temperature Ts. I do. Thereby, in the cooling operation or the heating operation, the temperature of the air in the indoor space (S) converges to the set temperature Ts.

<Training operation>
Next, the training operation of the room air conditioner (20) will be described. When the operation mode of the operation switching setting unit (41) is set to “forging operation” and the operation is started, the following training operation is performed.

  As shown in FIG. 4, when the training operation is started, a low temperature holding operation is performed over a time t1. That is, at the time t1 (12.5 minutes), the target temperature of the room air conditioner (20) becomes the low temperature side target temperature Tmin (22 ° C.). That is, the air conditioning control unit (50) controls the room air conditioner (20) so that the temperature around the occupant in the indoor space (S) approaches the low temperature side target temperature Tmin. Here, the air conditioning control unit (50) controls the operation frequency and start / stop of the compressor (22) so that the temperature of the intake air detected by the suction temperature sensor (35), for example, approaches the low temperature side target temperature Tmin. I do.

  Specifically, when the training operation is started when the room temperature is 22 ° C. or lower, the heating operation is performed at a target temperature of 18 ° C. or higher and 22 ° C. or lower in order to perform a low temperature holding operation. On the other hand, when the forging operation is started when the room temperature is 22 ° C. or higher and 25 ° C., the cooling operation is performed at the target temperature of 22 ° C. in order to perform the low temperature holding operation.

  Here, during the low temperature holding operation, when the air is cooled by the indoor heat exchanger (25), moisture in the air is condensed and collected by the drain pan (36). Thereby, the dehumidified air is blown out from the air outlet (33). In this way, when applying a cold stimulus to the human body, the temperature difference on the cold stimulus side is increased by reducing the humidity in the vicinity of the human body even when the same temperature change is given to the human body. And the effect of contraction of peripheral skin blood vessels is increased.

  As described above, when the low temperature holding operation is executed, the room occupant is given a cold stimulus. As a result, the peripheral blood vessels of the occupants contract. And such a cold stimulus is continuously given to the occupant over time t1. Therefore, at time t1, the occupant's peripheral skin blood vessels are surely contracted. In order to reliably contract the peripheral blood vessels of the occupants in this manner, the execution time t1 of the first low temperature holding operation is preferably set to 12.5 minutes or more.

  And when time t1 passes and the first low temperature holding operation | movement is complete | finished, a high temperature holding operation is performed immediately after the completion | finish. That is, at the time t2 (35 minutes), the target temperature of the room air conditioner (20) becomes the high temperature side target temperature Tmax (28 ° C.). That is, the air conditioning control unit (50) controls the room air conditioner (20) so that the temperature around the occupant in the indoor space (S) approaches Tmax. More specifically, the air conditioning control unit (50), for example, determines the operating frequency and the frequency of the compressor (22) so that the temperature of the intake air detected by the intake temperature sensor (35) approaches the high temperature side target temperature Tmax. Control stop.

  Here, the temperature gradient at the time of switching from the cold stimulus to the warm stimulus is preferably set so as to satisfy the condition of 6 ° C./25 minutes or more, as indicated by a broken line arrow in FIG. Further, in order to maintain thermal stimulation, an air flow temperature of 28 ° C. or higher is realized for at least 10 minutes of time t2 (35 minutes) (see the hatched area in FIG. 4).

  Here, during the high temperature holding operation, moisture is released into the air from the humidifying nozzle (61), and the angle of the flap (34) is changed so that the hot air reaches the human body directly from the air outlet (33). Like to do. In this way, when applying a cold stimulus to the human body, while reducing the humidity near the human body, while increasing the humidity near the human body when applying a thermal stimulus, the same temperature change is applied to the human body. Even if it is provided, the temperature difference between the cold stimulation side and the thermal stimulation side can be increased, and the effect of contraction and expansion of the peripheral skin blood vessels is increased.

  As described above, when the high temperature holding operation is performed immediately after the low temperature holding operation is finished, the temperature around the occupant rapidly increases. For this reason, steep thermal stimulation is given to the person in the room. As a result, the peripheral blood vessels of the occupant rapidly expand. Then, such thermal stimulation is continuously given to the occupants over time t2. For this reason, at time t2, the skin peripheral blood vessels that were in the contracted state until immediately before the start of the high-temperature holding operation can be reliably brought into the expanded state. In order to reliably expand the peripheral blood vessels of the occupants in this way, the execution time t2 of the high temperature holding operation is preferably set to 35 minutes or more.

In addition, in the case of a cold occupant, the skin peripheral blood vessels tend to be in a contracted state. For this reason, by making the execution time of the high-temperature holding operation immediately after the execution time of the first low-temperature holding operation longer, it becomes easier to transition the skin peripheral blood vessels of such chilled occupants to the expanded state. When the high temperature holding operation ends after the time t2 elapses, the second low temperature holding operation is executed immediately after the end. That is, at the time t3 (12.5 minutes), the target temperature of the room air conditioner (20) becomes the low temperature side target temperature Tmin (22 ° C.) again. Thereby, the temperature around the occupant falls to the low temperature side target temperature Tmin. As a result, the occupant is given a steep cold stimulus, and the peripheral blood vessels of the occupant rapidly contract. Note that if the execution time of the second low-temperature holding operation is too short, the cold stimulus provided to the occupants becomes insufficient. For this reason, the execution time t3 of the second low-temperature holding operation is preferably 12.5 minutes or longer.

  Here, when the room temperature is 25 ° C. or more (temperature gradient 1 in FIG. 4), the angle of the flap (34) is changed so that the cool air is directly reached to the occupant and the sensible temperature is lowered.

  Further, when the room temperature is 20 ° C. or higher and 25 ° C. or lower during the low temperature holding operation (temperature gradient 2 in FIG. 4), the air blowing operation of the room air conditioner (20) is performed in order to prevent the perceived temperature from being excessively lowered by the air flow. Is stopped. And when room temperature is 20 degrees C or less (temperature gradient 3 of FIG. 4), heating operation is performed by target temperature 20 degreeC. Note that the moisture in the air is dehumidified by the indoor heat exchanger (25) also during the second low temperature holding operation.

  When the time t3 elapses and the second low temperature holding operation is completed, the training operation is finished and the normal operation is automatically executed. As a result, the target temperature of the room air conditioner (20) becomes the set temperature Ts, and the above-described cooling operation and heating operation are performed. Therefore, after the training operation, the temperature of the indoor space (S) approaches the set temperature Ts, so that the comfort of the indoor space (S) is promptly improved.

  FIG. 5 is a graph showing changes in fingertip skin temperature. As shown in FIG. 5, when applying a thermal stimulus to the human body, while reducing the humidity in the vicinity of the human body, while increasing the humidity in the vicinity of the human body when applying the thermal stimulus, It can be seen that the temperature difference from the thermal stimulation side is large. Thereby, the effect of the contraction and expansion action of the skin peripheral blood vessel can be increased.

  The air conditioning control unit (50) controls the room air conditioner (20) so that the temperature in the vicinity of the occupants in the indoor space (S) approaches the target temperature. Specifically, by incorporating a temperature sensor in the remote control of the room air conditioner (20), the temperature in the vicinity of the occupant is directly detected, and the value of the room air conditioner (20) is set so that the value becomes the target temperature. The set temperature is feedback controlled.

  FIG. 6 is an example of a temperature variation pattern, and is a time chart showing a change in target temperature of the physiological function activating device. As shown in FIG. 6, it can be seen that the target temperature can be stably controlled by directly detecting the temperature in the vicinity of the occupant and feeding back the set temperature of the room air conditioner (20).

  In addition to directly detecting the temperature in the vicinity of the occupant, the temperature in the vicinity of the occupant is indirectly estimated by estimating the temperature change of the air blown out from the air outlet (33). The set temperature of the room air conditioner (20) may be feedback controlled so that the detected temperature becomes the target temperature.

  FIG. 7 is a graph showing the relationship between the distance between the room air conditioner and the human body and the temperature and speed of the airflow reaching the human body. As shown in FIG. 7, based on the temperature and wind speed of the air blown from the air outlet (33), the distance between the room air conditioner (20) and the human body, etc. Can be estimated. Then, the set temperature of the room air conditioner (20) may be controlled so that the estimated value becomes the target temperature.

  Note that the air wind speed can be directly detected by, for example, a wind speed sensor, or indirectly based on, for example, the air volume of the indoor fan (27), the angle of the flap (34) of the outlet (33), or the like. You can also ask for. In addition, if the distance between the room air conditioner (20) and the human body is determined in advance by specifying a position for the user to receive the training operation, or by detecting the position of the human body using an infrared sensor or the like, Good.

  As another control method for the room air conditioner (20), the set temperature of the room air conditioner (20) may be fixed. FIG. 8 is a time chart showing a change in the target temperature when the temperature variation pattern is fixed. In the example shown in FIG. 8, when performing the thermal stimulation, the set temperature of the room air conditioner (20) is fixed at 21 ° C. Further, when performing thermal stimulation, the set temperature is fixed at 28 ° C. Note that the set temperature is merely an example, and a plurality of set temperature patterns are prepared based on the size of the room, the amount of clothes of the occupants, the distance between the room air conditioner (20) and the occupants, etc. It is preferable.

<< Other Embodiments >>
About the said embodiment, it is good also as following structures.

  For example, in the embodiment, the room air conditioner (20) is used as the air conditioning unit that changes the temperature in the room. However, for example, a fan coil unit, a heater, or a Peltier element may be used as the air conditioning unit (20). That is, the air conditioning unit (20) may be any means as long as it can heat or cool the air.

  Moreover, in the said embodiment, about the structure which provided the adsorption | suction rotor (63), the heater (64), the cooler (65), and the humidification water tank (66) in the outdoor casing (62) as a means to humidify air. Although described, it is not limited to this form. For example, an ultrasonic type that discharges water into fine particles by ultrasonic waves, a vaporization type that humidifies air through a filter containing water, a heating type that boiles water by a heater and releases its water vapor by a fan, an adsorbent Various forms such as a desiccant type in which moisture is adsorbed on an adsorption heat exchanger that supports and heat is exchanged with a refrigerant flowing through the adsorption heat exchanger to release moisture are applicable.

  As described above, the present invention provides a highly practical effect that the physiological function activating device can improve the physiological function activation action, and is therefore extremely useful and industrially applicable. Is expensive.

10 Physiological function activation device
20 Room air conditioner
25 Indoor heat exchanger (dehumidification part)
34 Flap
50 Air conditioning control unit
61 Humidification nozzle (humidifier)

Claims (5)

An air conditioning unit (20) that changes the temperature of the room in order to give a thermal stimulus and a cold stimulus to the human body,
A high temperature holding operation in which the target temperature of the air conditioning unit (20) is held at a high temperature side target temperature for applying the thermal stimulus over a predetermined time, and the target temperature of the air conditioning unit (20) is over a predetermined time. An air-conditioning control unit (50) for performing a temperature fluctuation operation in which a low-temperature holding operation that is lower than a high-temperature side target temperature and held at a low-temperature side target temperature for applying the cold energy stimulus is executed at least once;
A physiological function activating device comprising: a dehumidifying unit (25) for dehumidifying the indoor air during the low temperature holding operation. An air conditioning unit (20) that changes the temperature of the room in order to give a thermal stimulus and a cold stimulus to the human body,
A high temperature holding operation in which the target temperature of the air conditioning unit (20) is held at a high temperature side target temperature for applying the thermal stimulus over a predetermined time, and the target temperature of the air conditioning unit (20) is over a predetermined time. An air-conditioning control unit (50) for performing a temperature fluctuation operation in which a low-temperature holding operation that is lower than a high-temperature side target temperature and held at a low-temperature side target temperature for applying the cold energy stimulus is executed at least once;
A physiological function activating device comprising: a humidifying unit (61) for humidifying the indoor air during the high temperature holding operation. In claim 2,
A physiological function activating device comprising a dehumidifying unit (25) for dehumidifying the indoor air during the low temperature holding operation. In claim 2 or 3,
The air-conditioning unit (20) is controlled so as to allow the air humidified by the humidifying unit (61) to reach the human body directly from the air outlet (33) during the high-temperature holding operation. Physiological function activation device characterized. In claim 4,
The air outlet (33) is provided with a flap (34) capable of changing the air direction of the air,
The flap angle of the flap (34) is changed so that the air humidified by the humidifying unit (61) can reach the human body directly from the air outlet (33) during the high temperature holding operation. Physiological function activation device characterized.

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