JP6533700B2 - Bathroom drying system - Google Patents

Description

  The technology disclosed herein relates to a bathroom drying system.

  The bathroom drying system disclosed in Patent Document 1 comprises a gas heat source machine for heating a heat medium, an air heating means for exchanging heat between the heat medium heated by the gas heat source machine and the air, and air in the bathroom air. The air circulation means is supplied to the heating means, and the air heated by the air heating means is returned to the inside of the bathroom, and the ventilation means for ventilating the air in the bathroom with the air outside the bathroom.

Unexamined-Japanese-Patent No. 9-273761

  In the bathroom drying system disclosed in Patent Document 1, since the heat medium is heated by the gas heat source with high heating capacity, the temperature of the heat medium can be easily raised, and the air in the bathroom is made high. Can. However, in the bathroom drying system of Patent Document 1, since the heat medium is continuously heated by the gas heat source machine, energy efficiency is limited. That is, the energy consumption amount has been increased by continuing to heat the heat medium by the gas heat source device.

  Thus, the present specification provides an energy efficient bathroom drying system.

  The bathroom drying system disclosed herein includes a gas heat source unit that heats the heat medium, and a heat pump that heats the heat medium. Also, the bathroom drying system includes an air heating means for exchanging heat between the gas heat source and / or the heat medium heated by the heat pump and the heat medium, and the air in the bathroom sent to the air heating means and heated by the air heating means The air circulation means for returning air to the inside of the bathroom, the ventilation means for ventilating the air in the bathroom with the air outside the bathroom, the humidity detection means for detecting the humidity of the air in the bathroom, and the control means. The control means is configured to perform a drying operation in which the ventilation means ventilates with air outside the bathroom while the air in the bathroom is heated by the air heating means and the air circulating means. The control means heats the heat medium only by the heat pump from the first operation mode of operating the gas heat source to heat the heat medium based on the humidity detected by the humidity detection means in the drying operation. The gas heat source unit and the heat pump are controlled to switch to the operation mode. In the first operation mode in the drying operation, the heat medium may be heated only by the gas heat source device, or the heat medium may be heated by the gas heat source device and the heat pump.

  According to the above-described bathroom drying system, the heat medium is heated by the heat pump alone after the heat medium is heated by operating the gas heat source machine with high heating capacity, instead of continuing to heat the heat medium with the gas heat source machine. The heat pump does not have very high heating capacity, but the energy consumption when heating the heat medium is smaller than that of the gas heat source. Therefore, in the drying operation, energy efficiency can be improved by switching from the first operation mode to the second operation mode. In the bathroom drying system described above, the first operation mode is switched to the second operation mode based on the humidity of the air in the bathroom detected by the humidity detection means. For example, when the humidity of the air in the bathroom is low at the beginning of the drying operation, the heat medium is heated by the gas heat source machine in the first operation mode. As a result, the temperature of the air in the bathroom can be rapidly increased by the high temperature heat medium heated by the gas heat source machine, and the evaporation of the water from the clothes or the like in the bathroom can be promoted. Thereafter, when the moisture contained in the clothes or the like in the bathroom evaporates sufficiently and the humidity of the air in the bathroom becomes sufficiently high, the first operation mode is switched to the second operation mode. The heat medium is heated only by the heat pump. As a result, heat can be supplied to the air in the bathroom by the heat medium heated by the energy efficient heat pump, and the drying operation can be continued. Thus, by switching from the first operation mode to the second operation mode according to the humidity of the air in the bathroom, it is possible to suppress the heating of the heat medium by the gas heat source machine more than necessary, and the energy efficiency is improved. can do.

  In the above-mentioned bathroom drying system, the control means controls the gas heat source so as to heat the heat medium to the first temperature in the first operation mode, and the heat medium is controlled to the first temperature in the second operation mode. The heat pump may be configured to control the heat pump to heat up to a low second temperature.

According to this configuration, in the second operation mode, the heat pump is heated to the second temperature by the heat pump. Therefore, the heat efficiency is improved by lowering the heating efficiency as the heating temperature decreases. If it is done, energy efficiency can be further improved.

  Further, in the above-described bathroom drying system, the control means causes the temperature of the heat medium heated by the heat pump to decrease from the second temperature to a third temperature lower than the second temperature in the second operation mode. The heat pump may be configured to control and then control the heat pump to rise to a fourth temperature that is higher than the third temperature.

  According to this configuration, even if the amount of heat supplied from the air heating means to the air in the bathroom is reduced as the drying progresses, the temperature of the heat medium is increased thereafter to increase the temperature in the bathroom from the air heating means. The amount of heat supplied to the air can be increased to provide a better finish for drying.

  Moreover, the bathroom drying system disclosed in the present specification includes a gas heat source device that heats the heat medium, and a heat pump that heats the heat medium. Also, the bathroom drying system includes an air heating means for exchanging heat between the gas heat source and / or the heat medium heated by the heat pump and the heat medium, and the air in the bathroom sent to the air heating means and heated by the air heating means The air circulation means for returning air into the bathroom, the ventilation means for ventilating the air in the bathroom with the air outside the bathroom, the temperature detection means for detecting the temperature of the air in the bathroom, and the control means are provided. The control means is configured to perform a drying operation in which the ventilation means ventilates with air outside the bathroom while the air in the bathroom is heated by the air heating means and the air circulating means. The control means heats the heat medium only by the heat pump from the first operation mode of operating the gas heat source to heat the heat medium based on the temperature detected by the temperature detection means in the drying operation. The gas heat source unit and the heat pump are controlled to switch to the operation mode. In the first operation mode in the drying operation, the heat medium may be heated only by the gas heat source device, or the heat medium may be heated by the gas heat source device and the heat pump.

  According to the above-described bathroom drying system, for example, when the temperature of the air in the bathroom is low at the beginning of the drying operation, the heat medium is heated by the gas heat source machine in the first operation mode. As a result, the temperature of the air in the bathroom can be rapidly increased by the high temperature heat medium heated by the gas heat source machine, and the evaporation of the water from the clothes or the like in the bathroom can be promoted. Thereafter, when the moisture contained in the clothes or the like in the bathroom evaporates sufficiently and the temperature of the air in the bathroom becomes sufficiently high, the first operation mode is switched to the second operation mode. The heat medium is heated only by the heat pump. As a result, heat can be supplied to the air in the bathroom by the heat medium heated by the energy efficient heat pump, and the drying operation can be continued.

It is a figure showing typically the composition of the bathroom drying system concerning an example. It is a figure showing typically the composition of the drier concerning an example. It is a flowchart which shows the process which a control apparatus performs in the drying driving | operation which concerns on 1st Example. It is a figure which shows an example of the relationship between drying time, heat carrier temperature, and absolute humidity. It is a flowchart which shows the process which a control apparatus performs in the drying driving | operation which concerns on 2nd Example.

(First embodiment)
As shown in FIG. 1, the bathroom drying system 2 includes a heat pump 50, a water circulation system 7, and a control device 100.

  The heat pump 50 includes a refrigerant circulation path 52 for circulating a refrigerant (for example, HFC refrigerant such as R410A, natural refrigerant such as CO 2, isobutane, propane, etc.), a gas-liquid heat exchanger 54 (evaporator), and a fan 56. , A compressor 51, a fluid heat exchanger 53 (condenser), and an expansion valve 55.

  The gas-liquid heat exchanger 54 exchanges heat between the outside air blown by the fan 56 and the refrigerant in the refrigerant circuit 52. The refrigerant in the low pressure and low temperature liquid state after passing through the expansion valve 55 is supplied to the gas-liquid heat exchanger 54. The gas-liquid heat exchanger 54 heats the refrigerant by heat exchange between the refrigerant and the outside air. The refrigerant is vaporized by being heated to be in a low pressure gaseous state.

  The refrigerant after passing through the gas-liquid heat exchanger 54 is supplied to the compressor 51. That is, the low pressure gaseous refrigerant is supplied to the compressor 51. As the refrigerant is compressed by the compressor 51, the refrigerant is in a high temperature / high pressure gas state. The compressor 51 delivers the compressed high-temperature high-pressure gaseous refrigerant to the fluid heat exchanger 53.

  The fluid heat exchanger 53 is supplied with the high-temperature high-pressure gaseous refrigerant sent from the compressor 51. The fluid heat exchanger 53 performs heat exchange between the refrigerant in the refrigerant circulation path 52 and the water (an example of a heat medium) in the second heating path 76 described later. The refrigerant loses heat and condenses as a result of heat exchange in the fluid heat exchanger 53. As a result, the refrigerant is in a liquid state of relatively low temperature and high pressure.

  The expansion valve 55 is supplied with a refrigerant in a relatively low temperature and high pressure liquid state after passing through the fluid heat exchanger 53. The refrigerant is depressurized by passing through the expansion valve 55, and becomes a liquid state of low temperature and low pressure. The refrigerant that has passed through the expansion valve 55 is sent to the gas-liquid heat exchanger 54.

  In the heat pump 50, when the compressor 51 is operated, the refrigerant in the refrigerant circulation path 52 circulates in the order of the compressor 51, the fluid heat exchanger 53, the expansion valve 55, and the gas-liquid heat exchanger 54. Thus, the water flowing through the second heating passage 76 in the fluid heat exchanger 53 is heated.

  The water circulation system 7 includes a cistern 70, a gas heat source 60, and a dryer 30. The water circulation system 7 further includes a circulation forward passage 72, a first heating passage 73, a high temperature heating passage 77, a dryer supply passage 75, a second heating passage 76, and a circulation return passage 79. The water circulation system 7 circulates the water in the cistern 70.

  The cistern 70 is a container whose top is open, and stores water inside. The upstream end of the circulation forward path 72 is connected to the cistern 70. A circulation pump 74 is interposed in the circulation forward passage 72. When the circulation pump 74 is driven, the water in the cistern 70 flows into the circulation path 72.

  The downstream end of the circulation forward passage 72 is branched into a first heating passage 73 and a dryer supply passage 75. A gas heat source device 60 is interposed in the first heating path 73. The gas heat source unit 60 heats the water in the first heating path 73 by the heat obtained by burning the gas. The gas heat source unit 60 has a higher ability to heat water than the heat pump 50. That is, the gas heat source unit 60 has a larger amount of heat supplied to water per unit time than the heat pump 50.

  A thermistor 91 is interposed downstream of the gas heat source unit 60 in the first heating path 73. The thermistor 91 detects the temperature of the water in the first heating path 73 after passing through the gas heat source unit 60. The downstream end of the first heating path 73 is connected to the cistern 70. The water flowing through the first heating path 73 returns to the cistern 70. Further, a high temperature heating path 77 branches from the first heating path 73 downstream of the gas heat source machine 60. In the high temperature heating path 77, a high temperature heating device 78 such as a fan control vector is interposed. The downstream end of the high temperature heating path 77 is connected to the cistern 70.

  The downstream end of the drier feed path 75 is connected to the drier 30. The water that has flowed through the dryer supply path 75 is supplied to the dryer 30. The dryer 30 dries the air in the bathroom 40 using the heat of the water supplied from the dryer supply path 75. The used water is discharged from the dryer 30 and flows into the second heating passage 76. The configuration of the dryer 30 will be described in detail later.

  The upstream end of the second heating path 76 is connected to the dryer 30. The second heating path 76 passes through the fluid heat exchanger 53 of the heat pump 50. The water flowing through the second heating path 76 is heated by the fluid heat exchanger 53. A thermistor 92 is interposed downstream of the fluid heat exchanger 53 of the second heating passage 76. The thermistor 92 detects the temperature of water in the second heating path 76 after passing through the fluid heat exchanger 53.

  The downstream end of the second heating passage 76 is connected to the circulation return passage 79. The downstream end of the circulation return path 79 is connected to the cistern 70. The water flowing through the circulation return path 79 returns to the cistern 70.

  Next, the dryer 30 will be described. As shown in FIG. 2, the dryer 30 includes an air heater 33, an air circulation device 34, a ventilation device 35, a humidity sensor 31, and a bathroom thermistor 32. The dryer 30 is installed in the bathroom 40. The dryer 30 is attached to the ceiling of the bathroom 40, for example.

  Water is present in the air in the bathroom 40. For example, when the laundry (clothes containing moisture) is present in the bathroom 40, the moisture contained in the laundry is evaporated and is present as water vapor in the air in the bathroom 40.

  Water is supplied to the air heater 33 from the above-described dryer supply path 75. Further, the air in the bathroom 40 is sent to the air heater 33 by the air circulation device 34. The air heater 33 heats the air in the bathroom 40 sent to the air heater 33 by the air circulation device 34. The air heater 33 heats the air by the heat of the water sent to the air heater 33 by the dryer feed path 75. The air heater 33 heats air by heat exchange between water and air.

  Further, the air circulation device 34 returns the air heated by the air heater 33 into the bathroom 40. The air circulation device 34 introduces the heated air into the bathroom 40 by blowing air. The air circulation device 34 of the present embodiment is, for example, a line flow fan. The air circulation device 34 circulates the air in the bathroom 40. Air is circulated between the inside of the bathroom 40 and the air heater 33, and is heated by the air heater 33 in the process of circulation.

  The ventilator 35 ventilates the air in the bathroom 40 with the air outside the bathroom 40. The ventilation device 35 exhausts the air in the bathroom 40 to the outside of the bathroom 40 and sucks the air outside the bathroom 40 into the bathroom 40. The ventilating device 35 discharges the air with relatively high humidity to the outside of the bathroom 40 and sucks the air with relatively low humidity into the inside of the bathroom 40. The ventilator 35 of this embodiment is, for example, a sirocco fan.

  The humidity sensor 31 detects the humidity of the air in the bathroom 40. The humidity sensor 31 continuously detects the humidity. The humidity in this example is absolute humidity. The bathroom thermistor 32 detects the temperature of air in the bathroom 40. The bathroom thermistor 32 continuously detects the temperature.

  The control device 100 is configured to control the operation of each component of the heat pump 50 and the water circulation system 7.

  Next, the operation of the bathroom drying system 2 of the present embodiment will be described.

(Drying operation)
The drying operation is an operation to dry the air in the bathroom 40. That is, the drying operation is an operation for removing the water contained in the air in the bathroom 40. FIG. 3 is a flowchart showing processing executed by the control device 100 in the drying operation.

  When the user instructs execution of the drying operation, in S11 of FIG. 3, the control device 100 operates the circulation pump 74 at a predetermined number of revolutions. When the circulation pump 74 is operated, the water in the cistern 70 flows through the circulation forward passage 72 and branches into the first heating passage 73 and the dryer supply passage 75. The water branched into the first heating path 73 passes through the gas heat source unit 60 and returns to the cistern 70. On the other hand, the water branched into the dryer supply passage 75 passes the dryer 30, the second heating passage 76, the fluid heat exchanger 53 of the heat pump 50, and the circulation return passage 79 in this order to return to the cistern 70. Thus, the operation of the circulation pump 74 causes the water in the cistern 70 to circulate.

  In the subsequent S12, the control device 100 operates the heat pump 50. By operating the heat pump 50, the refrigerant in the refrigerant circulation path 52 passing through the fluid heat exchanger 53 turns into a high temperature and high pressure gas state. Further, when the water flowing through the second heating passage 76 passes through the fluid heat exchanger 53, the heat is heated by the heat of the refrigerant in the refrigerant circulation passage 52. The water heated by the fluid heat exchanger 53 passes through the circulation return path 79 and returns to the cistern 70.

  In the subsequent S13, the control device 100 operates the gas heat source unit 60. Thus, the water passing through the first heating path 73 is heated by the gas heat source unit 60. The gas heat source unit 60 heats the water so that the temperature of the water detected by the thermistor 91 becomes a first temperature (for example, 72 ° C.) (see FIG. 4). The water heated by the gas heat source 60 flows through the first heating path 73 and returns to the cistern 70.

  The water circulating in the water circulation system 7 is heated by the heat pump 50 and the gas heat source unit 60 by the steps S12 and S13 (first operation mode). The water heated by the heat pump 50 and the gas heat source machine 60 passes through the air heater 33 of the dryer 30 in the process of circulating the water circulation system 7.

  In the subsequent S14, the control device 100 operates the dryer 30. The operation of the dryer 30 causes the air circulation device 34 to send the air in the bathroom 40 to the air heater 33. The air heater 33 heats the air sent to the air heater 33 by the air circulation device 34. The air heater 33 heats the air by the heat of the water passing through the air heater 33. The air heated by the air heater 33 is returned into the bathroom 40 by the air circulation device 34. Thereby, the air in the bathroom 40 is heated while circulating.

  When the air in the bathroom 40 is heated, as shown in FIG. 4, the temperature in the bathroom 40 rises with the passage of time. As a result, the saturated water vapor pressure of the air in the bathroom 40 rises. At the same time, for example, the moisture of the laundry present in the bathroom 40 evaporates, and the amount of water vapor present in the air in the bathroom 40 rises. As a result, the humidity of the air in the bathroom 40 rises with the passage of time.

  Further, by the operation of the dryer 30, the ventilator 35 of the dryer 30 exhausts the air in the bathroom 40 out of the bathroom 40 and sucks the air outside the bathroom 40 into the bathroom 40. As a result, the humid air in the bathroom 40 is exhausted out of the bathroom 40. Also, low humidity air outside the bathroom 40 is drawn into the bathroom 40. When the ventilation device 35 ventilates the air in the bathroom 40 and the air outside the bathroom 40, and the moisture content of the clothes decreases, the humidity of the air in the bathroom 40 decreases after a certain period of time (see FIG. 4).

In continuing S15, control device 100 judges whether the humidity in bathroom 40 detected by humidity sensor 31 is more than predetermined standard humidity (for example, 25 g / m ³ ). When the humidity in the bathroom 40 is equal to or higher than the reference humidity (for example, 25 g / m ³ ), the control device 100 determines Yes in S15, skips the following S16, and proceeds to S17. On the other hand, when the humidity in the bathroom 40 is not higher than the reference humidity (less than the reference humidity), the control device 100 determines No in S15 and proceeds to S16.

  In S16, the control device 100 determines whether the humidity in the bathroom 40 detected by the humidity sensor 31 is decreasing. When the humidity in the bathroom 40 is decreasing, the control device 100 determines that the result is YES in S16, and proceeds to S17. On the other hand, when the humidity in the bathroom 40 is not falling (the humidity in the bathroom 40 is rising), the control device 100 determines No in S16, and returns to S15.

  At S17, the control device 100 stops the gas heat source unit 60. According to S15, S16, and S17, the control device 100 causes the humidity in the bathroom 40 to rise above the predetermined reference humidity, or the humidity in the bathroom 40 starts to fall without rising to the predetermined reference humidity. In the case, the gas heat source unit 60 is stopped. By the stop of the gas heat source machine 60, the circulating water is not heated by the gas heat source machine 60 and is heated only by the heat pump 50 (second operation mode). Moreover, in S17, the control device 100 recognizes the humidity of the air in the bathroom 40 when the gas heat source device 60 is stopped. The control device 100 recognizes the humidity at this time as the first humidity H1.

  At S18, the control device 100 controls the heat pump 50. By control of the control device 100, the heat pump 50 heats the water such that the temperature of the water detected by the thermistor 92 becomes the second temperature (for example, 60 ° C.) (see FIG. 4). The second temperature (60 ° C.) is a temperature lower than the first temperature (72 ° C.).

In subsequent S19, the control device 100, the humidity humidity in the bathroom 40 detected by the humidity sensor 31 has lowered by a predetermined humidity from the first humidity (H1) (e.g. 6.5g / ^{m 3)} (H1- It is judged whether it is 6.5 g / m ³ or less. If the humidity in the bathroom 40, a first humidity (H1) from the predetermined humidity (6.5g / ^{m 3)} or less only the lowered humidity (H1-6.5g / ^{m 3),} the control device 100 S19 And the process proceeds to S20. On the other hand, when the humidity in the bathroom 40 is not lower than the first humidity minus the predetermined humidity (higher than H 1-6.5 g / m ³ ), the control device 100 determines No in S19 and stands by Do.

  If the controller 100 determines YES in S19, the controller 100 recognizes the humidity of the air in the bathroom 40 at that time in S20. The controller 100 recognizes the humidity as the second humidity H2.

  In the subsequent S21, the control device 100 controls the heat pump 50. By control of the control device 100, the heat pump 50 heats the water such that the temperature of the water detected by the thermistor 92 becomes the third temperature (for example, 45 ° C.) (see FIG. 4). The third temperature (45 ° C.) is a temperature lower than the second temperature (60 ° C.).

In subsequent S22, the control unit 100, humidity humidity bath 40 detected by the humidity sensor 31 has lowered by a predetermined humidity from the second humidity (H2) (e.g. 6.5g / ^{m 3)} (H2- It is judged whether it is 6.5 g / m ³ or less. If the humidity in the bathroom 40, a second humidity (H2) from a predetermined humidity (6.5g / ^{m 3)} by lowering the humidity (H2-6.5g / ^{m 3)} or less, the control device 100 S22 And the process proceeds to S23. On the other hand, if the humidity in the bathroom 40 is not lower than the second humidity minus the predetermined humidity (higher than H 2-6.5 g / m ³ ), the control device 100 determines No in S22 and stands by Do.

  In the subsequent S23, the control device 100 controls the heat pump 50. By control of the control device 100, the heat pump 50 heats the water so that the temperature of the water detected by the thermistor 92 becomes the fourth temperature (for example, 60 ° C.) (see FIG. 4). The fourth temperature (60 ° C.) is a temperature higher than the third temperature (45 ° C.). Thus, the control device 100 controls the heat pump 50 so as to increase again after the temperature of water once decreases.

  As described above, the control device 100 controls the gas heat source unit 60 and the heat pump 50 based on the humidity in the bathroom 40 detected by the humidity sensor 31. Thereafter, when a predetermined time has elapsed, the control device 100 ends the drying operation.

  In the above, the structure and the operation content of the bathroom drying system 2 of a present Example were demonstrated. As apparent from the above description, as shown in FIG. 1, the bathroom drying system 2 of the present embodiment includes a gas heat source machine 60 for heating water (an example of a heat medium) and a heat pump 50 for heating water. Have. Also, the bathroom drying system 2 sends an air heater 33 that exchanges heat between the gas heat source device 60 and the water heated by the heat pump 50 and the air, and sends the air in the bathroom 40 to the air heater 33. And an air circulating device 34 for returning the air heated by the air supply into the bathroom 40. The bathroom drying system 2 also includes a ventilation device 35 for ventilating the air in the bathroom 40 with the air outside the bathroom 40, a humidity sensor 31 for detecting the humidity of the air in the bathroom 40, and the control device 100. . In this bathroom drying system 2, the control device 100 performs a drying operation in which the ventilation device 35 ventilates with the air outside the bathroom 40 while heating the air in the bathroom 40 with the air heater 33 and the air circulation device 34. Is configured. The control device 100 heats the water only by the heat pump 50 from the first operation mode in which the gas heat source device 60 is operated to heat the water based on the humidity detected by the humidity sensor 31 in the drying operation. The gas heat source unit 60 and the heat pump 50 are configured to be controlled to switch to the operation mode.

  According to such a configuration, instead of continuing to heat the water by the gas heat source machine 60, the gas heat source machine 60 is stopped, and thereafter the water is heated only by the heat pump 50. Since the heat pump 50 consumes less energy than the gas heat source device 60, switching from the gas heat source device 60 to the heat pump 50 can improve energy efficiency. Further, by switching the operation mode based on the humidity detected by the humidity sensor 31, the energy efficiency can be further improved. In the present embodiment, when the humidity of the air in the bathroom 40 is low at the beginning of the drying operation, water is heated by the gas heat source machine 60 in the first operation mode. As a result, the temperature of the air in the bathroom 40 can be rapidly increased by the high temperature water heated by the gas heat source machine 60, and the evaporation of water from the clothes or the like in the bathroom 40 can be promoted. Thereafter, when the moisture contained in the clothes etc. in the bathroom 40 is sufficiently evaporated and the humidity of the air in the bathroom 40 becomes sufficiently high, or the humidity of the air in the bathroom 40 starts to fall Switches from the first operating mode to the second operating mode, and heats the water only by the heat pump 50. As a result, heat can be supplied to the air in the bathroom 40 by the water heated by the heat pump 50 with high energy efficiency, and the drying operation can be continued. As described above, since the gas heat source unit 60 can be switched to the heat pump 50 according to the humidity of the air in the bathroom 40, it is possible to suppress the water from being heated by the gas heat source unit 60 more than necessary. Therefore, energy consumption can be suppressed and energy efficiency can be improved.

  Further, in the above embodiment, the control device 100 controls the gas heat source unit 60 so as to heat water to a first temperature (for example, 72 ° C.) in the first operation mode. Further, the control device 100 controls the heat pump 50 so as to heat water to a second temperature (for example, 60 ° C.) lower than the first temperature (72 ° C.) in the second operation mode. According to such a configuration, by controlling the gas heat source unit 60 and the heat pump 50, the temperature of water can be lowered stepwise. Therefore, as the drying progresses, the amount of heat supplied to the air in the bathroom 40 can be reduced to realize energy saving.

  Further, in the above embodiment, in the second operation mode, the controller 100 performs the third temperature in which the temperature of water heated by the heat pump 50 is lower than the second temperature (e.g., 60 ° C.) The heat pump is controlled to drop to (eg 45 ° C.) and then the heat pump is controlled to rise to a fourth temperature (eg 60 ° C.) higher than the third temperature. According to such a configuration, even if the amount of heat supplied to the air in the bathroom 40 is reduced as drying progresses, the air is supplied to the air in the bathroom 40 by raising the temperature of the water thereafter. Heat quantity can be increased. Thereby, for example, after the laundry in the bathroom 40 is almost dried, the air in the bathroom 40 can be heated again by the heat of the hot water, so that the finish of the laundry drying can be well performed.

  As mentioned above, although one Example was described, a specific aspect is not limited to the said Example. In the following description, the same components as those in the above description will be assigned the same reference numerals and descriptions thereof will be omitted. For example, in the above embodiment, the water is heated by the gas heat source 82 and the heat pump 50 in the first operation mode, but the present invention is not limited to this configuration. In another embodiment, the water may be heated only by the gas heat source 82 in the first operation mode. Then, in the second operation mode, the water is heated only by the heat pump 50.

Second Embodiment
Further, in the above embodiment, the control device 100 is configured to switch from the first operation mode to the second operation mode based on the humidity detected by the humidity sensor 31, but the present invention is limited to this configuration. It is not a thing. In another embodiment, as shown in FIG. 5, after the control device 100 operates the dryer 30 in S14, in the subsequent S35, the control device 100 detects the temperature in the bathroom 40 detected by the bathroom thermistor 32. It is determined whether the temperature is higher than a reference temperature (for example, 36 ° C.). When the temperature in the bathroom 40 is equal to or higher than the reference temperature (for example, 36 ° C.), the control device 100 determines Yes in S35, and proceeds to S17. On the other hand, when the temperature in the bathroom 40 is not higher than the reference temperature (less than the reference temperature), the control device 100 determines No in S35 and stands by.

  At S17, the control device 100 stops the gas heat source unit 60. The control device 100 stops the gas heat source unit 60 when the temperature in the bathroom 40 rises to a predetermined reference temperature or more by S35 and S17. By the stop of the gas heat source machine 60, the circulating water is not heated by the gas heat source machine 60 and is heated only by the heat pump 50 (second operation mode).

  As is clear from the above description, in the bathroom drying system 2 of the present embodiment, the control device 100 operates the gas heat source machine 60 based on the temperature detected by the bathroom thermistor 32 in the drying operation to generate water. The gas heat source unit 60 and the heat pump 50 are controlled to switch from the first operation mode to heat to the second operation mode to heat water only by the heat pump 50.

  As mentioned above, although the specific example of this invention was described in detail, these are only an illustration and do not limit a claim. The art set forth in the claims includes various variations and modifications of the specific examples illustrated above. The technical elements described in the present specification or the drawings exhibit technical usefulness singly or in various combinations, and are not limited to the combinations described in the claims at the time of application. In addition, the techniques exemplified in the present specification or the drawings can simultaneously achieve a plurality of purposes, and achieving one of the purposes itself has technical utility.

2: Bathroom drying system 7: Water circulation system 30: Dryer 31: Humidity sensor 32: Bathroom thermistor 33: Air heater 34: Air circulation device 35: Ventilation device 40: Bathroom 50: Heat pump 51: Compressor 52: Refrigerant circuit 53: fluid heat exchanger 54: gas-liquid heat exchanger 55: expansion valve 56: fan 60: gas heat source 70: cisturn 72: circulation forward path 73: first heating path 74: circulation pump 75: dryer supply path 76: Second heating path 77: high temperature heating path 78: high temperature heating device 79: circulation return path 91: thermistor 92: thermistor 100: control device

Claims (4)

A gas heat source unit for heating a heat medium;
A heat pump for heating a heat medium,
Air heating means for exchanging heat between the gas heat source unit and / or a heat medium heated by the heat pump and air;
Air circulating means for sending the air in the bathroom to the air heating means and for returning the air heated by the air heating means into the bathroom;
Ventilation means to ventilate the air in the bathroom with the air outside the bathroom,
Humidity detection means for detecting the humidity of air in the bathroom;
And control means,
The control means is configured to execute a drying operation to ventilate the air outside the bathroom with the ventilating means while heating the air in the bathroom with the air heating means and the air circulating means.
The control means determines whether the humidity detected by the humidity detection means is equal to or higher than a predetermined reference humidity or the humidity detected by the humidity detection means is decreasing in the drying operation . The gas heat source machine and the heat pump are controlled to switch from the first operation mode in which the gas heat source machine is operated to heat the heat medium to the second operation mode in which the heat medium is heated only by the heat pump The bathroom drying system is configured to: A gas heat source unit for heating a heat medium;
A heat pump for heating a heat medium,
Air heating means for exchanging heat between the gas heat source unit and / or a heat medium heated by the heat pump and air;
Air circulating means for sending the air in the bathroom to the air heating means and for returning the air heated by the air heating means into the bathroom;
Ventilation means to ventilate the air in the bathroom with the air outside the bathroom,
Humidity detection means for detecting the humidity of air in the bathroom;
And control means,
The control means is configured to execute a drying operation to ventilate the air outside the bathroom with the ventilating means while heating the air in the bathroom with the air heating means and the air circulating means.
In the drying operation, the control means operates the gas heat source device based on the humidity detected by the humidity detection means to heat the heat medium from the first operation mode in which the heat medium is heated only by the heat pump. The gas heat source unit and the heat pump are controlled to switch to a second operation mode to heat, and the gas heat source is heated to heat the heat medium to a first temperature in the first operation mode. A bathroom drying system configured to control a machine and to control the heat pump to heat the heat transfer medium to a second temperature lower than the first temperature in the second operation mode .   The control means controls the heat pump so that the temperature of the heat medium heated by the heat pump drops from the second temperature to a third temperature lower than the second temperature in the second operation mode. The bathroom drying system according to claim 2, configured to control the heat pump to rise to a fourth temperature, which is then higher than the third temperature. A gas heat source unit for heating a heat medium;
A heat pump for heating a heat medium,
Air heating means for exchanging heat between the gas heat source unit and / or a heat medium heated by the heat pump and air;
Air circulating means for sending the air in the bathroom to the air heating means and for returning the air heated by the air heating means into the bathroom;
Ventilation means to ventilate the air in the bathroom with the air outside the bathroom,
Temperature detection means for detecting the temperature of air in the bathroom;
And control means,
The control means is configured to execute a drying operation to ventilate the air outside the bathroom with the ventilating means while heating the air in the bathroom with the air heating means and the air circulating means.
The control unit operates the gas heat source unit to heat the heat medium when it is determined that the temperature detected by the temperature detection unit is equal to or higher than a predetermined reference temperature in the drying operation. A bathroom drying system configured to control the gas heat source unit and the heat pump to switch from the mode to a second operation mode in which the heat medium is heated only by the heat pump.

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