JP2020085342A - Bathroom heating and drying device with ventilation function - Google Patents

Abstract

To provide a bathroom heating and drying device with a ventilation function, capable of more reducing power consumption.SOLUTION: A bathroom heating and drying device 1 with a ventilation function comprises: a heating and drying unit 10 that heats and dries a bathroom with hot water from a heat source device 30; a ventilation unit 20 that ventilates at least the bathroom by an air blower 23; a first microcomputer that controls the heating and drying unit 10; and a second microcomputer that can communicate with the first microcomputer, and controls the ventilation unit 20. Here, when the ventilation unit 20 is driven by the second microcomputer, the heating and drying unit 10 shifts to a power saving state based on the heating and drying unit 10 being in a non-operating state.SELECTED DRAWING: Figure 1

Description

The present invention relates to a bathroom heating/drying apparatus having a ventilation function, which has a function of heating and drying a bathroom and at least a function of ventilating a bathroom.

BACKGROUND ART Conventionally, a bathroom heating/drying device that heats and dries a bathroom with hot water supplied from a heat source device is known. Further, this type of bathroom heating/drying device may be provided with a ventilation function for ventilating other rooms such as a dressing room together with the bathroom. For example, Patent Document 1 below describes a bathroom heating/ventilating device having a heating function, a drying function, and a ventilation function. This device is further provided with a mist function for injecting hot and cold water into a mist.

JP, 2006-218159, A

In the bathroom heating/drying device with a ventilation function having the above configuration, reduction in power consumption is desired. In particular, when the 24-hour ventilation function for performing constant ventilation is executed as the ventilation function, the power consumption by the ventilation function increases. Therefore, it is required to reduce power consumption on the heating and drying unit side as much as possible.

In view of this problem, it is an object of the present invention to provide a bathroom heating/drying device with a ventilation function that can further reduce power consumption.

A bathroom heating/drying apparatus with a ventilation function according to a main aspect of the present invention is a heating/drying unit for heating and drying a bathroom with hot water from a heat source, a ventilation unit for ventilating at least a bathroom by blowing air from a blower, and the heating/drying unit. And a second microcomputer that is capable of communicating with the first microcomputer and that controls the ventilation unit. Here, the heating/drying unit shifts to a power-saving state when the heating/drying unit is in a non-operating state when the ventilation unit is driven by the second microcomputer.

According to the bathroom heating/drying apparatus with a ventilation function of the present aspect, even if the ventilation unit is driven, the heating/drying unit shifts to the power saving state if the heating/drying unit is in the non-operating state. As a result, useless power consumption in the heating/drying unit is suppressed. Therefore, it is possible to reduce power consumption in the bathroom heating/drying apparatus with a ventilation function.

The bathroom heating/drying apparatus with a ventilation function according to this aspect may be configured such that, in the power saving state, the first microcomputer shifts to the power saving mode.

With this configuration, when the heating/drying unit is in the power saving state, at least power consumption in the first microcomputer can be suppressed. Therefore, it is possible to reduce power consumption in the bathroom heating/drying apparatus with a ventilation function.

Further, the bathroom heating/drying apparatus with a ventilation function according to this aspect includes a shutoff unit that shuts off power supply to the first microcomputer, and in the power saving state, the shutoff unit causes the first microcomputer to operate. Can be configured to cut off the supply of power to.

With this configuration, when the heating/drying unit is in the power saving state, at least the power consumption of the first microcomputer can be reduced. Therefore, it is possible to more effectively reduce the power consumption in the bathroom heating/drying apparatus with a ventilation function.

In this case, the bathroom heating/drying apparatus with a ventilation function is configured such that an operation input signal is input to the second microcomputer, and the second microcomputer supplies power to the first microcomputer. The shutoff unit may be configured to supply power to the first microcomputer when a signal of an operation input regarding the heating and drying unit is received in the shutoff state.

According to this configuration, power can be smoothly supplied to the first microcomputer according to an operation input for operating the heating/drying unit. Therefore, it is possible to smoothly execute the heating or drying function according to the operation input.

Further, the bathroom heating/drying apparatus with a ventilation function according to this aspect includes a power supply circuit capable of changing the power supply voltage, and reduces the power supply voltage of the power supply circuit to the control board of the heating/drying unit in the power saving state. Can be configured as follows.

With this configuration, when the heating/drying unit is in the power saving state, at least power consumption in the control board of the heating/drying unit can be suppressed. Therefore, it is possible to more effectively reduce the power consumption in the bathroom heating/drying apparatus with a ventilation function.

In this configuration, when the power supply circuit also supplies a power supply voltage to the control board of the ventilation unit, the bathroom heating/drying device with a ventilation function is supplied to the control board of the ventilation unit in the power saving state. It may be configured to include a voltage adjustment circuit that maintains the power supply voltage at the voltage before the transition to the power saving state.

According to this configuration, even if the power supply voltage in the power supply circuit is lowered due to the transition to the power saving state, the power supply voltage supplied to the control board of the ventilation unit by the voltage adjustment circuit before the transition to the power saving state. Maintained at the voltage of. Therefore, the operation of the ventilation unit can be stably maintained regardless of the transition to the power saving state.

In the bathroom heating/drying apparatus with a ventilation function according to this aspect, the second microcomputer may be configured to perform a 24-hour ventilation function that causes the ventilation unit to operate at all times.

Since the power consumption increases when the ventilation function is performed for 24 hours, it is necessary to suppress the power consumption on the heating and drying unit side. In this respect, according to the bathroom heating/drying apparatus with a ventilation function of the present aspect, useless power consumption on the heating/drying unit side can be suppressed as described above, so that the power consumption of the bathroom heating/drying apparatus with a ventilation function is suppressed. be able to.

As described above, according to the present invention, it is possible to provide a bathroom heating/drying apparatus with a ventilation function capable of further reducing power consumption.

The effects and significance of the present invention will be more apparent from the description of the embodiments below. However, the embodiment described below is merely an example for embodying the present invention, and the present invention is not limited to what is described in the embodiment below.

FIG. 1 is a diagram showing a configuration of a bathroom heating/drying apparatus with a ventilation function according to the first embodiment. FIG. 2 is a diagram showing a circuit block of the bathroom heating/drying apparatus with a ventilation function according to the first embodiment. FIG. 3A is a flowchart showing a process of switching the heating/drying unit between the power saving state and the normal state according to the first embodiment. FIG. 3B is a flowchart showing processing performed in the power saving state according to the first embodiment. FIG. 4 is a diagram showing a circuit block of the bathroom heating/drying apparatus with a ventilation function according to the second embodiment. FIG. 5A is a flowchart showing a process of switching the heating/drying unit between the power saving state and the normal state according to the second embodiment. FIG. 5B is a flowchart showing the operation signal transmission processing from the second microcomputer to the first microcomputer according to the second embodiment. FIG. 6 is a diagram showing a circuit block of a bathroom heating/drying apparatus with a ventilation function according to the third embodiment. FIG. 7 is a flowchart showing a process of switching the heating/drying unit between the power saving state and the normal state according to the third embodiment. FIG. 8: is a figure which shows the circuit block of the bathroom heating drying apparatus with a ventilation function which concerns on Embodiment 4. As shown in FIG. FIG. 9 is a flowchart showing processing performed in the power saving state according to the fourth embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<Embodiment 1>
FIG. 1 is a diagram showing a configuration of a bathroom heating/drying apparatus 1 with a ventilation function according to the first embodiment. In FIG. 1, the heating/drying unit 10 and the ventilation unit 20 are in a state where the housings 10a and 20a are shown in cross section and the inside is seen through.

As shown in FIG. 1, the bathroom heating/drying apparatus 1 with a ventilation function includes a heating/drying unit 10, a ventilation unit 20, a heat source device 30, and a remote controller 40 (hereinafter, referred to as a “remote control 40”). The heating/drying unit 10 and the ventilation unit 20 are integrated with each other.

The heating/drying unit 10 includes a suction port 11 for sucking air and a discharge port 12 for discharging air in a lower portion of the housing 10a. The suction port 11 and the discharge port 12 are exposed inside the bathroom from the ceiling of the bathroom. The outlet 12 is provided with a louver (not shown) for changing the air discharge direction. The louver is driven by a motor. Inside the housing 10a, an air flow path P1 is formed between the suction port 11 and the discharge port 12. The heat exchanger 13 and the blower 14 are arranged in the flow path P1.

The heat exchanger 13 warms the air passing through the heat exchanger 13 with the hot water supplied from the heat source device 30. The outward pipe 31 and the return pipe 32 are connected to the heat exchanger 13. When the heating function and the drying function are executed, hot water heated by the burner or the like in the heat source device 30 circulates in the heat exchanger 13 via the pipes 31 and 32. As a result, the air passing through the heat exchanger 13 is warmed.

The blower 14 blows air so that the air flows from the suction port 11 to the discharge port 12 through the flow path P1. The blower 14 is, for example, a cross flow fan, and is driven by a motor (not shown).

When the heating function and the drying function are executed, the air in the bathroom taken in through the suction port 11 is discharged into the bathroom from the discharge port 12 through the heat exchanger 13 by the air blow by the blower 14. As the air passes through the heat exchanger 13, the air is warmed and dehumidified. After that, air is discharged into the bathroom through the exhaust port 12 to heat and dry the inside of the bathroom. In this way, the bathroom is heated and dried.

The ventilation unit 20 includes a housing 20a having a suction port 21 for sucking air and a discharge port 22 for discharging air. The suction port 21 is connected to the bathroom. The discharge port 22 is connected to the outside through a duct. Although only one suction port 21 is provided in the housing 20a in FIG. 1, another suction port may be provided in the housing 20a. This suction port is connected to a room other than the bathroom (for example, a dressing room) via a duct.

Inside the housing 20a, an air flow path P2 is formed between the suction port 21 and the discharge port 22. The blower 23 is arranged in the flow path P2. The blower 23 is, for example, a sirocco fan, and is driven by a motor (not shown).

When the ventilation function is executed, the air blown by the blower 23 causes the air taken in from the suction port 21 to be discharged to the outside from the discharge port 22 through the flow path P2. This ventilates the bathroom and the like. In the present embodiment, a 24-hour ventilation function for constantly operating the ventilation unit 20 is executed.

Control boards 15 and 24 are installed in the heating/drying unit 10 and the ventilation unit 20, respectively. A remote controller 40 is communicably connected to the control board 15 on the heating and drying unit 10 side. Further, the control boards 15 and 24 are communicably connected to each other. A circuit portion for driving and controlling the heating and drying unit 10 and the heat source device 30 is arranged on the control board 15, and a circuit portion for driving and controlling the ventilation unit 20 is arranged on the control board 24. ..

The remote controller 40 includes an operation unit 41 and a display unit 42. The operation unit 41 includes an operation button for starting and stopping the operation of the bathroom heating/drying apparatus 1 with a ventilation function, and a plurality of operation buttons for executing and stopping the heating, drying and ventilation functions. Predetermined information is displayed on the display unit 42 when each function is executed.

When the control board 15 receives from the remote controller 40 a signal corresponding to an operation input to the operation unit 41, the control board 15 executes control according to the received signal. For example, when the received signal is a signal related to the heating function or the drying function, the control board 15 controls the heat source unit 30 and the heating/drying unit 10. For example, as this control, the control board 15 controls the drive of the blower 14, the drive of the burner in the heat source device 30, the drive of the louver installed at the outlet 12, and the control board 15 is further arranged in the flow path P1 and the like. Based on the detected value of the thermistor (not shown), control for adjusting the temperature of the hot water supplied from the heat source device 30 is performed.

If the signal received from the remote controller 40 is a signal related to the ventilation function, the control board 15 transfers this signal to the control board 24. As a result, the control board 24 performs ventilation control based on the signal. In this control, the blower 23 is driven.

FIG. 2 is a diagram showing a circuit block of the bathroom heating/drying apparatus 1 with a ventilation function.

As shown in FIG. 2, the control board 15 on the heating and drying unit 10 side includes a microcomputer 101 (hereinafter, referred to as “first microcomputer 101”), a switching power supply 102, a regulator 103, a communication circuit 104, and a load. Group 105 and are arranged.

The first microcomputer 101 controls each circuit unit arranged on the control board 15 according to a predetermined control program.

The switching power supply 102 generates a DC power supply voltage of 12 V and 18 V from a commercial power supply of AC 100 V. Of these, the DC 12V power supply voltage is used in the control board 15. Here, a power supply voltage of DC 12V is supplied to the communication circuit 104 and the load group 105. The regulator 103 generates a constant voltage of 5 V DC from a power supply voltage of 12 V DC supplied from the switching power supply 102 and supplies the voltage to the first microcomputer 101. The first microcomputer 101 operates with a constant voltage of DC 5 V supplied from the regulator 103.

The communication circuit 104 communicates with the remote controller 40. The communication circuit 104 is connected to the remote controller 40 by a communication line. The first microcomputer 101 communicates with the remote controller 40 via the communication circuit 104. The communication circuit 104 and the remote controller 40 may communicate by wireless communication.

The load group 105 includes a circuit that drives a drive motor of the blower 14, a circuit that drives a drive motor of a louver provided at the outlet 12, and a thermistor that detects the temperature of warm air discharged from the outlet 12. The load group of the drive system and the sensor system of the heating and drying unit 10, such as the circuit for controlling the heating and drying unit, is included. The load group 105 is driven by a power supply voltage of DC 12 V generated by the switching power supply 102.

A microcomputer 201 (hereinafter, referred to as “second microcomputer 201”), a fan drive circuit 202, and a regulator 203 are arranged on the control board 24 on the ventilation unit 20 side.

The second microcomputer 201 controls each circuit unit arranged on the control board 24 according to a predetermined control program. The second microcomputer 201 is communicably connected to the first microcomputer 101.

The fan drive circuit 202 drives the motor of the blower 23 arranged in the ventilation unit 20 under the control of the second microcomputer 201. The fan drive circuit 202 is supplied with a power supply voltage of DC 18 V generated by the switching power supply 102.

The regulator 203 generates a constant voltage of 5 V DC from the power supply voltage of 18 V DC supplied from the switching power supply 102 and supplies the voltage to the second microcomputer 201. The second microcomputer 201 operates with a constant voltage of 5 V DC supplied from the regulator 203.

The signal from the remote controller 40 is transmitted to the first microcomputer 101 via the communication circuit 104. When the received signal is related to the function of the heating/drying unit 10, the first microcomputer 101 performs control (heating and ventilation control) based on the signal. When the received signal is related to the function of the ventilation unit 20, the first microcomputer 101 transfers the received signal to the second microcomputer 201. In response to this, the second microcomputer 201 performs control (ventilation control) based on the signal. As described above, in the first embodiment, the second microcomputer 201 controls the 24-hour ventilation.

By the way, in the bathroom heating/drying apparatus 1 with a ventilation function having the above configuration, reduction of power consumption is desired. Particularly, as described above, when 24-hour ventilation is performed as the ventilation function, power consumption by the ventilation function increases. Therefore, it is required to reduce power consumption on the heating and drying unit 10 side as much as possible.

Therefore, in the first embodiment, control for further reducing the power consumption of the heating/drying unit 10 is performed. Specifically, when the ventilation unit 20 is driven, control is performed to shift the heating/drying unit 10 to the power saving state based on the heating/drying unit 10 being in the non-operating state. Hereinafter, this control will be described.

FIG. 3A is a flowchart showing a process of switching the heating/drying unit 10 between the power saving state and the normal state.

The first microcomputer 101 determines whether or not a certain time has elapsed after the operation of the heating/drying unit 10 has stopped (S101) (S102). Specifically, the first microcomputer 101 determines that the operation signal for the heating/drying unit 10 has not been received from the remote controller 40 for a certain period of time after the operation of the heating/drying unit 10 is stopped.

When the operation of the heating/drying unit 10 is stopped for a certain period of time (S102: YES), the first microcomputer 101 sets the heating/drying unit 10 in the power saving state (S103).

FIG. 3B is a flowchart showing the processing performed in the power saving state of step S103.

The first microcomputer 101 reduces the frequency of the internal clock as compared with that in the normal operation, and shifts to the power saving mode (S201). For example, when the frequency of the internal clock of the first microcomputer 101 can be switched among three stages of high speed, medium speed, and low speed, the first microcomputer 101 sets the frequency of the internal clock to high during normal operation, and saves power. Then, the frequency of the internal clock is switched to medium speed or low speed. As a result, the processing speed of the first microcomputer 101 is reduced, but the power consumption of the first microcomputer 101 is reduced.

At the same time, the first microcomputer 101 stops peripheral functions that do not need to be operated when the heating/drying unit 10 is in a non-operating state (S202). For example, the first microcomputer 101 stops the function for the load group 105 in FIG. 2 in step S202. On the other hand, since the communication circuit 104 needs to be able to continuously receive the operation signal from the remote controller 40, the function of the communication circuit 104 is not stopped in step S202. Similarly, regarding the functions of the switching power supply 102 and the regulator 103, these functions are not stopped in step S202 because the first microcomputer 101 needs to continue to operate in the power saving mode.

Returning to FIG. 3A, the first microcomputer 101 determines whether or not an operation signal regarding the heating/drying unit 10 is received from the remote controller 40 after shifting the heating/drying unit 10 to the power saving state (S103). (S104). Then, when the operation signal regarding the heating/drying unit 10 is received (S104: YES), the first microcomputer 101 returns the heating/drying unit 10 to the normal state (S105). Specifically, the first microcomputer 101 switches the internal clock at high speed and operates the peripheral functions stopped in the power saving state. As a result, the function of the heating/drying unit 10 according to the operation signal is executed.

<Effect of Embodiment 1>
According to this embodiment, the following effects can be achieved.

Even if the ventilation unit 20 is driven by 24-hour ventilation, if the heating/drying unit 10 is in the non-operating state, the heating/drying unit 10 shifts to the power saving state. As a result, useless power consumption in the heating/drying unit 10 is suppressed. Therefore, the power consumption in the bathroom heating/drying apparatus 1 with a ventilation function can be reduced.

As shown in FIG. 3B, in the power saving state, the first microcomputer 101 shifts to the power saving mode (S201). Thereby, when the heating/drying unit 10 is in the power saving state, the power consumption in the first microcomputer 101 is suppressed. Therefore, the power consumption in the bathroom heating/drying apparatus 1 with a ventilation function can be reduced.

<Embodiment 2>
In the first embodiment, the communication circuit 104 that communicates with the remote controller 40 is mounted on the control board 15 on the heating and drying unit 10 side. On the other hand, in the second embodiment, the control circuit 24 on the ventilation unit 20 side is equipped with a communication circuit that communicates with the remote controller 40.

FIG. 4 is a diagram showing a circuit block of the bathroom heating/drying apparatus 1 with a ventilation function according to the second embodiment.

As described above, in the second embodiment, the communication circuit 211 is arranged on the control board 24 on the ventilation unit 20 side. The communication circuit 211 is supplied with a power supply voltage of DC 18 V generated by the switching power supply 102. The other circuit parts are the same as those in the first embodiment.

FIG. 5A is a flowchart showing a process of switching the heating/drying unit 10 between the power saving state and the normal state according to the second embodiment. FIG. 5B is a flowchart showing the operation signal transmission processing from the second microcomputer 201 to the first microcomputer 101 according to the second embodiment.

The processing of steps S101 to S103 and S105 of FIG. 5A is the same as that of FIG. In the second embodiment, after the heating/drying unit 10 shifts to the power saving state (S103), the first microcomputer 101 receives an operation signal regarding the function of the heating/drying unit 10 from the second microcomputer 201 ( (S110), the heating and drying unit 10 returns to the normal state (S105).

As shown in FIG. 5B, when the second microcomputer 201 receives the operation signal from the remote controller 40 (S301: YES), the second microcomputer 201 determines whether the operation signal is an operation signal related to the function of the heating/drying unit 10. (S302). Then, when the operation signal is an operation signal related to the function of the heating/drying unit 10 (S302), the second microcomputer 201 transmits the operation signal to the first microcomputer 101 (S303).

When the first microcomputer 101 receives the operation signal from the second microcomputer 201 by the process of FIG. 5B in the power saving state (S110) (S110: YES), the heating and drying unit 10 is returned to the normal state ( S105). As a result, as described above, the internal clock frequency of the first microcomputer 101 is switched at high speed, and the suspended peripheral functions are restored to the operating state.

The process of FIG. 5B is executed not only when the heating and drying unit 10 is in the power saving state, but also when the heating and drying unit 10 is in the normal state. In addition, in steps S101 to S103 of FIG. 5A, the first microcomputer 101 performs heating when no operation signal is received from the second microcomputer 201 for a certain period after the operation of the heating/drying unit 10 is stopped. The drying unit 10 is shifted to the power saving state.

Also in the second embodiment, the same effect as that of the first embodiment can be obtained.

In the flowchart of FIG. 5A, as described above, the first microcomputer 101 determines whether or not the heating/drying unit 10 is in the non-operating state for a certain period, and the heating/drying unit 10 is in the power saving state. However, the second microcomputer 201 may determine whether the heating/drying unit 10 is in a non-operating state for a certain period of time and shift the heating/drying unit 10 to the power saving state.

In this case, for example, when the operation of the heating/drying unit 10 is stopped, a signal indicating this is transmitted from the first microcomputer 101 to the second microcomputer 201. After receiving this signal, the second microcomputer 201 is a signal for shifting the heating/drying unit 10 to the power saving state when the operation signal regarding the function of the heating/drying unit 10 is not received from the remote controller 40 for a certain period of time. Is transmitted to the first microcomputer 101. In response to this, the first microcomputer 101 shifts the heating and drying unit 10 to the power saving state.

With this configuration, the same effect as that of the first embodiment can be obtained.

<Embodiment 3>
In the first and second embodiments, the first microcomputer 101 is set to the power saving mode in the power saving state. However, in the third embodiment, the power supply voltage to the first microcomputer 101 is cut off in the power saving state. It

FIG. 6 is a diagram showing a circuit block of the bathroom heating/drying apparatus 1 with a ventilation function according to the third embodiment.

In the third embodiment, the circuit block of the second embodiment shown in FIG. 4 is provided with a cutoff unit 110 for cutting off the supply of the power supply voltage. The cutoff unit 110 is a switch that can be opened and closed under the control of the second microcomputer 201. For example, the blocking unit 110 can be configured by a switching element such as a FET (Field effect transistor). The other circuit parts are the same as those in the second embodiment.

FIG. 7 is a flowchart showing a process of switching the heating/drying unit 10 between a power saving state and a normal state according to the third embodiment. This processing is performed by the second microcomputer 201.

The second microcomputer 201 determines whether or not a certain period has elapsed after the heating/drying unit 10 has stopped (S401) (S402). For example, the second microcomputer 201 does not receive an operation signal regarding the function of the heating/drying unit 10 from the remote controller 40 for a certain period of time after receiving a notification from the first microcomputer 101 indicating that the operation of the heating/drying unit 10 has stopped. Determine that

If the determination in step S402 is YES, the second microcomputer 201 opens the cutoff unit 110 to cut off the supply of the power supply voltage to the first microcomputer 101 (S403). As a result, the heating/drying unit 10 shifts to the power saving state. After that, the second microcomputer 201 determines whether or not there is an operation instruction to the heating/drying unit 10, that is, whether or not an operation signal regarding the function of the heating/drying unit 10 is received from the remote controller 40 (S404). Then, when there is an operation instruction to the heating/drying unit 10 (S404: YES), the second microcomputer 201 closes the blocking unit 110 and supplies the power supply voltage to the first microcomputer 101 (S405).

According to the third embodiment, when the heating/drying unit 10 is in the power saving state, the power consumption in the first microcomputer 101 is reduced, so that the power consumption in the bathroom heating/drying apparatus 1 with a ventilation function can be more effectively performed. Can be reduced.

In addition, when the second microcomputer 201 receives the operation input signal for the heating and drying unit 10 from the remote controller 40 while the power supply voltage to the first microcomputer 101 is cut off, the second microcomputer 201 supplies power to the first microcomputer 101. The blocking unit 110 is controlled to supply the power. As a result, the power supply voltage can be smoothly supplied to the first microcomputer 101 in response to the operation input for operating the heating/drying unit 10 being given to the remote controller 40. Therefore, it is possible to smoothly execute the heating or drying function according to the operation input.

In the configuration of FIG. 6, the supply of the power supply voltage to the first microcomputer 101 is cut off in the power saving state, but the heating/drying unit 10 of the load group 105 is further operated when it is in the non-operating state. The supply of the power supply voltage may be cut off to the load group that is not necessary.

Further, the arrangement position of the blocking unit 110 may be changed to a position between the regulator 103 and the first microcomputer 101. When the voltage of DC 5 V generated by the regulator 103 is also supplied to a load other than the first microcomputer 101, the cutoff unit 110 is configured to supply the voltage from the regulator 103 to this load in the power saving state. May be arranged.

<Embodiment 4>
In the third embodiment, the supply of the power supply voltage to the first microcomputer 101 is cut off in the power saving state, but in the fourth embodiment, the power supply voltage generated by the switching power supply 102 is reduced in the power saving state. .

FIG. 8 is a diagram showing a circuit block of the bathroom heating/drying apparatus 1 with a ventilation function according to the fourth embodiment.

As shown in FIG. 8, in the fourth embodiment, a DCDC converter 221 for maintaining the voltage value at a constant value is added to the circuit block of the first embodiment shown in FIG. The value of the power supply voltage generated by the switching power supply 102 is changed by the control of the first microcomputer 101. The other circuit parts are the same as those in the first embodiment.

The process of switching the heating and drying unit 10 between the power saving state and the normal state is the same as the process of FIG. 3A in the above embodiment. However, the process for shifting to the power saving state (step S103 in FIG. 3A) is changed to the process in FIG. 9.

In the flowchart of FIG. 9, the process of step S210 is added to the flowchart of FIG. In step S210, the first microcomputer 101 reduces the power supply voltage generated by the switching power supply 102.

As described above, in the normal operation, the switching power supply 102 generates a power supply voltage of DC 12 V and a power supply voltage of DC 18 V, respectively. In the fourth embodiment, in the power saving state, the power supply voltage of 12 V DC is reduced to 8 V DC by the process of step S210, and accordingly, the power supply voltage of 18 V DC is reduced to 12 V DC. Here, the switching power supply 102 reduces the power supply voltage by controlling the switching cycle.

As described above, in the power saving state, by reducing the power supply voltage of the switching power supply 102, the power consumption of the switching power supply 102 can be reduced, and the control board 15 side to which the power supply voltage of the switching power supply 102 is supplied. Power consumption in the load group can be reduced. Note that the communication circuit 104 and the regulator 103 can operate with the reduced power supply voltage. In other words, the power supply voltage supplied from the switching power supply 102 is reduced within a range in which the communication circuit 104 and the regulator 103 can operate.

On the control board 24 side of the ventilation unit 20, in the power saving state, even if the power supply voltage supplied from the switching power supply 102 decreases, the same power supply voltage as in the normal state is supplied to each circuit unit. Specifically, the DCDC converter 221 maintains the voltage supplied to the regulator 203 and the fan drive circuit 202 at DC 18V. As a result, even when the supply voltage of the switching power supply 102 is reduced in the power saving state, each circuit section of the control board 24 of the ventilation unit 20 can be properly operated. Therefore, 24-hour ventilation can be stably performed.

According to the fourth embodiment, in the power saving state, the power supply voltage of the switching power supply 102 supplied to the control board 15 of the heating and drying unit 10 is reduced, so that the power consumption of the control board 15 can be suppressed. Therefore, the power consumption in the bathroom heating/drying apparatus 1 with a ventilation function can be reduced more effectively.

<Example of change>
Although the ventilation unit 20 performs the ventilation for 24 hours in the first to fourth embodiments, the ventilation unit 20 does not necessarily have to perform the ventilation for 24 hours. For example, the operating state of the ventilation unit 20 may be switched on/off according to an operation of turning on/off the ventilation function of the remote controller 40.

In the third embodiment, before the supply of the power supply voltage to the first microcomputer 101 is cut off, the second microcomputer 201 notifies the first microcomputer 101 that the power supply voltage is cut off. Good. For example, when a storage element such as a memory or an EEPROM (Electrically Erasable and Programmable Read-Only Memory) is connected to the first microcomputer 101, the first microcomputer 101 receives data from the storage element when receiving this notification. Is being written, the second microcomputer 201 is notified to wait for the power supply voltage to be cut off until the writing is completed, and when the data writing is completed, the second microcomputer 201 is notified of that and the power supply voltage is cut off. It may be allowed to.

In the first to fourth embodiments, the power supply voltage generated by the switching power supply 102 is 18 volts and 12 volts, but the value of the power supply voltage generated by the switching power supply 102 is not limited to this. Further, in the fourth embodiment, the power supply voltage is reduced from 12 volts and 18 volts to 8 volts and 12 volts in the power saving state, but the reduced voltage value is not limited to this.

The power supply voltage supplied to each of the circuit blocks and the circuit units shown in the first to fourth embodiments may be changed as appropriate. For example, the DCDC converter 221 shown in FIG. 8 may be replaced with another constant voltage circuit.

Further, in the above-described first to fourth embodiments, the bathroom heating/drying device 1 with a ventilation function can execute the heating and drying functions and the ventilation function. However, other functions such as the mist function and the ventilation function can be used. The attached bathroom heating/drying device 1 may be further provided.

In addition, the embodiment of the present invention can be variously modified within the scope of the claims.

1 Heating/Drying Device with Ventilation Function 10 Heating/Drying Unit 20 Ventilation Unit 30 Heat Source Machine 40 Remote Controller 41 Operation Unit 101 First Microcomputer (First Microcomputer)
102 Switching power supply (power supply circuit)
110 Blocking unit 201 Second microcomputer (second microcomputer)
221 DCDC converter (voltage adjustment circuit)

Claims (7)

A heating and drying unit that heats and dries the bathroom with hot water from the heat source,
A ventilation unit that ventilates at least the bathroom by blowing air with a blower,
A first microcomputer for controlling the heating and drying unit;
A second microcomputer communicable with the first microcomputer and controlling the ventilation unit;
The heating/drying unit shifts to a power saving state when the heating/drying unit is in a non-operating state when the ventilation unit is driven by the second microcomputer,
A bathroom heating and drying device with a ventilation function, which is characterized by that. The bathroom heating/drying apparatus with a ventilation function according to claim 1,
In the power saving state, the first microcomputer shifts to a power saving mode,
A bathroom heating and drying device with a ventilation function, which is characterized by that. The bathroom heating/drying apparatus with a ventilation function according to claim 1,
A shutoff unit for shutting off power supply to the first microcomputer;
In the power saving state, the cutoff unit cuts off power supply to the first microcomputer.
A bathroom heating and drying device with a ventilation function, which is characterized by that. The bathroom heating/drying apparatus with a ventilation function according to claim 3,
An operation input signal is input to the second microcomputer,
The second microcomputer turns on the power supply to the first microcomputer when receiving a signal of an operation input regarding the heating and drying unit in a state where the power supply to the first microcomputer is cut off. Controlling the interrupting part to supply,
A bathroom heating and drying device with a ventilation function, which is characterized by that. The bathroom heating/drying device with a ventilation function according to claim 1 or 2,
Equipped with a power supply circuit that can change the power supply voltage
In the power saving state, reduce the power supply voltage of the power supply circuit to the control board of the heating and drying unit,
A bathroom heating and drying device with a ventilation function, which is characterized by that. The bathroom heating/drying apparatus with a ventilation function according to claim 5,
The power supply circuit also supplies a power supply voltage to the control board of the ventilation unit,
In the power saving state, a voltage adjusting circuit for maintaining the power supply voltage supplied to the control board of the ventilation unit to the voltage before shifting to the power saving state,
A bathroom heating and drying device with a ventilation function, which is characterized by that. The bathroom heating/drying device with a ventilation function according to any one of claims 1 to 6,
The second microcomputer executes a 24-hour ventilation function for constantly operating the ventilation unit,
A bathroom heating and drying device with a ventilation function, which is characterized by that.

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