JP7182492B2 - Thermal equipment and thermal equipment system - Google Patents

Description

The technology disclosed in this specification relates to thermal equipment.

Patent Document 1 discloses a main control unit connected to a power supply unit for controlling the operation of a thermal device, a communication module connected to the power supply unit, a communication module between the power supply unit and the main control unit, and a power supply unit. and a switching unit disposed between a communication module. The switching unit can switch between a supply state in which power is supplied from the power supply unit to the main control unit and the communication module, and a cutoff state in which power supply from the power supply unit to the main control unit and the communication module is stopped. is.

JP 2018-40515 A

In the case of the thermal equipment of Patent Document 1, when the switching unit is switched from the supply state to the cutoff state in order to stop the power supply from the power supply unit to the main control unit, the power supply to the communication module is also stopped. Therefore, the thermal device cannot communicate with the external device using the communication module when the switching unit is in the cut-off state. In such thermal equipment, it is desired to continue to maintain a state in which communication with external equipment can be performed. In the case of the thermal equipment of Patent Literature 1, in order to maintain a state in which communication with an external device can be performed, it is necessary to keep the switching unit in the supply state. In this case, since power is always supplied from the power supply unit to the main control unit and the communication module, power consumption increases.

This specification provides a technique that can reduce power consumption while maintaining a state in which communication with an external device using a communication module can be performed.

The thermal equipment disclosed in this specification is connected to a power supply unit, and has a main control unit that controls the operation of the thermal equipment, and is connected to the power supply unit, and is capable of communicating with a plurality of external devices. and a communication module disposed between the main control unit and the power supply unit, a supply state in which power is supplied from the power supply unit to the main control unit, and a power supply state from the power supply unit to the main control unit. a switching unit capable of switching between a cutoff state in which the supply is stopped, and a switching unit in which power is constantly supplied to the communication module from the power supply unit, the thermal equipment information regarding the thermal equipment is transmitted to the plurality of external devices at predetermined intervals when the switching unit is in the state of to some specific external devices among the plurality of external devices.

According to the above configuration, power is supplied from the power supply unit to the communication module regardless of whether the switching unit is in the supply state or the cutoff state. That is, the communication module is maintained in a state capable of executing communication with a plurality of external devices even when the power supply from the power supply unit to the main control unit is stopped. Therefore, the thermal device can communicate with a plurality of external devices using the communication module even when power supply from the power supply unit to the main control unit is stopped. Also, the power consumption when the communication module operates is relatively small. Therefore, power consumption of the thermal equipment can be suppressed while maintaining a state in which communication with a plurality of external devices using the communication module can be performed.
Also, the communication module can transmit the thermal equipment information to the external equipment regardless of the state of the switching unit. Therefore, the user of the thermal equipment can know the state of the thermal equipment by checking the thermal equipment information transmitted to the external device even if the switching unit is in the cut-off state.
In addition, the communication module transmits the thermal equipment information to some specific external equipment among the plurality of external equipment when the switching unit is in the cut-off state. Therefore, when the switching unit is in the cut-off state, the power consumption of the thermal equipment can be suppressed compared to a configuration in which the thermal equipment information is transmitted to all of the plurality of external devices.

The above thermal equipment further includes a first voltage measurement unit that measures a voltage value supplied to the main control unit, and the thermal equipment information is the voltage supplied to the main control unit measured by the first voltage measurement unit. A first voltage-related information related to the value may be included.

According to the above configuration, the user of the thermal equipment can know whether or not the power supply to the main control unit is stopped by checking the first voltage-related information transmitted to the external equipment. can be done.

The thermal appliance described above may further comprise a power supply comprising a battery.

In the above configuration, the battery needs to be replaced when the power supplied from the battery to the main control unit and the communication module is insufficient. Frequent replacement of batteries is troublesome for users. As described above, the power consumption when the communication module operates is relatively small. Therefore, battery consumption is suppressed when the switching unit is in the cut-off state. Therefore, it is possible to reduce the frequency of battery replacement, thereby enhancing user convenience.

The above thermal equipment further includes a second voltage measurement unit that measures the voltage value of the battery, and the thermal equipment information includes second voltage-related information related to the voltage value of the battery measured by the second voltage measurement unit. may contain.

According to the above configuration, the user of the thermal equipment can determine whether or not the battery attached to the thermal equipment should be replaced by checking the second voltage relation information transmitted to the external device. Therefore, the user of the thermal equipment can replace the battery before the power supplied from the battery to the main controller and the communication module runs out. As a result, it is possible to prevent the thermal equipment from operating due to insufficient power supplied from the battery to the main control unit and the communication module.

A thermal equipment system disclosed herein comprises a thermal equipment and a plurality of external equipment. the thermal equipment is connected to a power supply unit, a main control unit that controls the operation of the thermal equipment; a communication module that is connected to the power supply unit and is capable of communicating with the plurality of external devices; A supply state in which power is supplied from the power supply unit to the main control unit and a power supply state in which power supply from the power supply unit to the main control unit is stopped is provided between the main control unit and the power supply unit. and a switching unit capable of switching between a cutoff state and a power supply unit, wherein the communication module is always supplied with power from the power supply unit, and the communication module, when the switching unit is in the supply state, The thermal equipment information about the thermal equipment is transmitted to the plurality of external devices at every predetermined cycle, and the thermal equipment information is transmitted to the plurality of external devices at each predetermined cycle when the switching unit is in the cut-off state. Send to some specified external devices.

According to the above configuration, power is supplied from the power supply unit to the communication module regardless of whether the switching unit is in the supply state or the cutoff state. That is, the communication module is maintained in a state capable of executing communication with a plurality of external devices even when the power supply from the power supply unit to the main control unit is stopped. Therefore, the thermal device can communicate with a plurality of external devices using the communication module even when power supply from the power supply unit to the main control unit is stopped. Also, the power consumption when the communication module operates is relatively small. Therefore, power consumption of the thermal equipment can be suppressed while maintaining a state in which communication with a plurality of external devices using the communication module can be performed.
Also, the communication module can transmit the thermal equipment information to the external equipment regardless of the state of the switching unit. Therefore, the user of the thermal equipment can know the state of the thermal equipment by checking the thermal equipment information transmitted to the external device even if the switching unit is in the cut-off state.
In addition, the communication module transmits the thermal equipment information to some specific external equipment among the plurality of external equipment when the switching unit is in the cut-off state. Therefore, when the switching unit is in the cut-off state, the power consumption of the thermal equipment can be suppressed compared to a configuration in which the thermal equipment information is transmitted to all of the plurality of external devices.

It is a figure which shows the structure of the heat cooking system which concerns on a present Example. It is a figure which shows the outline of a circuit structure of the heating cooker which concerns on a present Example. It is a flow chart of cooker information transmission processing of a present example. 4 is a flowchart of server processing of the embodiment. It is an example of each screen displayed on the portable terminal in the present embodiment. FIG. 4 is a sequence diagram of transmission of cooker information from a heat cooker in the embodiment.

(Configuration of cooking system 2; Fig. 1)
As shown in FIG. 1 , the heat cooking system 2 includes a heat cooker 10 , an alarm device 90 , a mobile terminal 100 , a management server 200 and a repeater 6 . The heating cooker 10, the alarm 90, and the repeater 6 are installed in the same house. In FIG. 1, a BT connection for executing Bluetooth (hereinafter referred to as "BT") communication according to the Bluetooth (registered trademark) system is indicated by a dashed line, and a Wi-Fi connection according to the Wi-Fi system is shown. A Wi-Fi connection for performing -Fi communication is indicated by a two-dot chain line.

The heating cooker 10 and the alarm device 90 can communicate with each other via BT communication. Moreover, the heating cooker 10 and the repeater 6 can communicate with each other via BT communication. Also, the cooking device 10 and the mobile terminal 100 can communicate with each other via BT communication. The mobile terminal 100 and the repeater 6 can each execute Wi-Fi communication according to the Wi-Fi system and connect to the Internet 4 . The management server 200 is connected to the Internet 4 . Cooking device 10 can access Internet 4 via relay device 6 .

(Configuration of heating cooker 10; FIGS. 1 and 2)
The configuration of the heating cooker 10 will be described with reference to FIGS. 1 and 2. FIG. FIG. 2 shows an outline of the circuit configuration of the heating cooker 10. As shown in FIG. As shown in FIG. 1 , the heating cooker 10 includes a stove burner 12 , a grill burner 14 , a power switch 16 , a main control board 20 , a BT module 30 and a battery mounting section 50 . A battery 52 is attached to the battery attachment portion 50 . The battery 52 is, for example, a dry battery or a rechargeable battery, and supplies electric power to each electronic component of the heating cooker 10 .

The stove burner 12 is a burner for heating an object to be heated (for example, a cooking container). A gas supply path (not shown) is connected to the stove burner 12 . The gas supply path is provided with a stove adjustment valve (not shown) for adjusting the amount of gas supplied to the stove burner 12 . The stove burner 12 is ignited by operating an igniter (not shown) while gas is being supplied to the stove burner 12 . In this embodiment, the cooking device 10 has three stove burners 12 . The grill burner 14 is a burner for heating foodstuffs stored in a grill chamber (not shown). The power switch 16 is a switch for switching between power ON and power OFF of the heating cooker 10 .

The main control board 20 includes a main control circuit 22 , a power cutoff circuit 26 and a communication circuit 28 . The main control circuit 22 includes a CPU 24 and a memory (not shown). The main control circuit 22 controls the operation of each component of the heating cooker 10 by executing processing based on the information stored in the memory by the CPU 24 .

As shown in FIG. 2, the power cut-off circuit 26 has a state in which power is being supplied from the battery 52 to the main control circuit 22 (hereinafter referred to as a "supply state") and a state in which power is being supplied from the battery 52 to the main control circuit 22. It is a switching circuit for switching between a state in which the supply of power is stopped (hereinafter referred to as a “cutoff state”). The power cutoff circuit 26 is provided between the main control circuit 22 and the battery 52 . The power cutoff circuit 26 operates in conjunction with the power switch 16 . That is, each time the power switch 16 is operated, the state of the power cutoff circuit 26 is switched. The communication circuit 28 is a circuit for executing communication with the BT module 30 (more specifically, the BT control circuit 32).

As shown in FIG. 1, the BT module 30 includes a BT control circuit 32, a main voltage measurement circuit 36, a battery voltage measurement circuit 38, a communication circuit 40, and a BT communication circuit . Note that the BT communication circuit 42 is omitted in FIG.

As shown in FIG. 2, the BT module 30 is provided in parallel with the main control board 20 . Therefore, power is supplied from the battery 52 to the BT module 30 even when the power cutoff circuit 26 is in the cutoff state. That is, the BT module 30 is constantly supplied with power from the battery 52 . For this reason, in this embodiment, when the heating cooker 10 is turned on, it means that power is being supplied to the main control board 20 and the BT module 30 . When the cooker 10 is powered off, it means that power supply to the main control board 20 is stopped and power is supplied to the BT module 30 .

The BT control circuit 32 includes a CPU 34 and a memory (not shown). The BT control circuit 32 controls the operation of each component of the BT module 30 by having the CPU 34 execute processing based on information stored in the memory.

The main voltage measurement circuit 36 is a circuit for measuring the main voltage MV, which is the voltage value supplied to the main control board 20 (specifically, the main control circuit 22). The battery voltage measurement circuit 38 is a circuit for measuring the battery voltage BV, which is the voltage value of the battery 52 . The communication circuit 40 is a circuit for executing communication with the main control board 20 (specifically, the main control circuit 22).

The BT communication circuit 42 in FIG. 1 is a wireless communication circuit for executing BT communication with an external device.

(Configuration of alarm device 90; FIG. 1)
The alarm 90 is a device that notifies the surroundings of the abnormality when there is an abnormality in the indoor carbon monoxide (CO) concentration. The alarm device 90 includes notification means 92 such as a buzzer, speaker, and lamp.

(Configuration of mobile terminal 100; FIG. 1)
The mobile terminal 100 is a portable terminal device such as a mobile phone and a smart phone. The mobile terminal 100 includes a display section 102 , an operation section 104 , a BT communication circuit 106 , a Wi-Fi communication circuit 108 and a terminal control circuit 110 . The display unit 102 is a display for displaying various information. The display unit 102 may function as a so-called touch panel (that is, the operation unit 104). The operation unit 104 has a plurality of keys. The user can input various instructions to the mobile terminal 100 by operating the operation unit 104 . The BT communication circuit 106 is a wireless communication circuit for executing BT communication with an external device. The mobile terminal 100 can execute BT communication with the heating cooker 10 via the BT communication circuit 106 . The Wi-Fi communication circuit 108 is a wireless communication circuit for executing Wi-Fi communication with an external device. The mobile terminal 100 can access the Internet 4 via the Wi-Fi communication circuit 108 . The terminal control circuit 110 has a CPU 112 and a memory 114 . The memory 114 is composed of a volatile memory, a nonvolatile memory, or the like. The terminal control circuit 110 controls the operation of each component of the mobile terminal 100 by causing the CPU 112 to execute processing based on the information stored in the memory 114 . A cooker application 116 is stored in the memory 114 . The cooker application 116 is a program provided by the vendor of the heat cooker 10, and is a program for causing the heat cooker 10 to perform automatic cooking. Cooker application 116 is also a program for checking the operating state of cooker 10 .

(Configuration of management server 200; FIG. 1)
Management server 200 is a server provided by the vendor of cooking device 10 . In the server processing of FIG. 4 described later, the management server 200 regularly heats cooker information including information about the operating state of the heating cooker 10 (state information described later, "power OFF", etc.), battery voltage BV, etc. It receives from the cooker 10 and accumulates the information. In addition, management server 200 transmits cooker information to mobile terminal 100 in response to receiving a request signal from mobile terminal 100 .

(Cooking device information transmission process; Fig. 3)
The cooker information transmission process executed by the BT control circuit 32 of the BT module 30 of the cooker 10 will be described with reference to FIG. The BT control circuit 32 starts the process of FIG. 3 when the battery 52 is set in the battery mounting portion 50 of the heating cooker 10, that is, when power supply from the battery 52 to the BT module 30 is started. . In the following processing, it is assumed that a BT connection is established between the heating cooker 10 and the relay device 6 and between the heating cooker 10 and the alarm device 90 .

In step S10, the BT control circuit 32 monitors whether a first predetermined time (eg, 10 seconds) has passed since the power of the heating cooker 10 was switched from OFF to ON. The BT control circuit 32 determines YES in step S10 when the elapsed time since the power of the heating cooker 10 is switched from OFF to ON has passed the first predetermined time, and the process proceeds to step S20.

In step S20, the BT control circuit 32 determines whether power is being supplied to the main control board 20 or not. Specifically, the BT control circuit 32 determines whether or not the main voltage MV measured by the main voltage measurement circuit 36 is equal to or higher than a first predetermined voltage (eg, 2.5V). When the main voltage MV is equal to or higher than the first predetermined voltage, the BT control circuit 32 determines YES in step S20, and the process proceeds to step S22. On the other hand, if the main voltage MV is less than the first predetermined voltage, the BT control circuit 32 determines NO in step S20, and the process proceeds to step S30.

In step S<b>22 , the BT control circuit 32 acquires the state information of the heating cooker 10 from the main control circuit 22 . Specifically, the BT control circuit 32 supplies a status information request to the main control circuit 22 via the communication circuits 28 and 40 . When the main control circuit 22 acquires the state information request, it identifies the operating states of the stove burner 12 and the grill burner 14 . Then, the main control circuit 22 supplies state information including the identified operating state to the BT control circuit 32 via the communication circuit 40 . For example, the status information may include "Stove ON" if at least one of the three stove burners 12 is in operation. The status information also includes "grill ON" when the grill burner 14 is in operation. The state information also includes "power ON" when the operation of the stove burner 12 and the grill burner 14 is stopped.

In step S<b>24 , the BT control circuit 32 transmits cooker information including the state information acquired from the main control circuit 22 to the repeater 6 and the alarm device 90 . Note that the BT control circuit 32 also transmits the cooker information to the mobile terminal 100 when the BT connection with the mobile terminal 100 is established. After step S24 ends, the process returns to step S10. In step S10 after step S24, the BT control circuit 32 monitors whether the first predetermined time has passed since the cooker information was transmitted.

On the other hand, when the main voltage MV is less than the first predetermined voltage, the BT control circuit 32 determines NO in step S20, and transmits the cooker information to the repeater 6 in step S30. The cooker information in step S<b>30 includes “power OFF” indicating that the cooker 10 is powered off, and the battery voltage BV measured by the battery voltage measurement circuit 38 . In addition, when the relay device 6 receives the cooking device information from the cooking device 10 , the relay device 6 transmits the cooking device information to the management server 200 via the Internet 4 . Thus, the BT control circuit 32 does not transmit cooking appliance information to the alarm device 90 and the mobile terminal 100 when the main voltage MV is less than the first predetermined voltage (NO in step S20). After step S30 ends, the process returns to step S10. In step S10 after step S30, the BT control circuit 32 monitors whether the first predetermined time has passed since the cooker information was transmitted.

(Server processing; Fig. 4)
Next, processing executed by the management server 200 will be described with reference to FIG. In step S<b>110 , the management server 200 monitors reception of cooker information from the heat cooker 10 . When the management server 200 receives cooker information from the heat cooker 10, it determines YES in step S110, and the process proceeds to step S112. In step S112, management server 200 stores the cooker information received in step S110 in a memory (not shown) of management server 200. FIG. After step S112 ends, the process returns to step S110.

Moreover, the management server 200 monitors reception of a request signal from the mobile terminal 100 in step S120 at the same time as monitoring in step S110. The request signal is a signal requesting transmission of cooking appliance information stored in the memory of management server 200 . For example, the user of the heating cooker 10 activates the cooking device application 116 in the portable terminal 100 when the user wants to know the operating state of the heating cooker 10 while away from home. Then, when the user performs an operation on the operation unit 104 of the portable terminal 100 to check the operating state of the cooking device 10 , a request signal is transmitted from the portable terminal 100 to the management server 200 . If the management server 200 receives a request signal from the mobile terminal 100, it determines YES in step S120, and the process proceeds to step S122.

In step S122, the management server 200 determines whether or not a connection with the repeater 6 via the Internet 4 is currently established. In this embodiment, the management server 200 transmits to the repeater 6 a confirmation signal for confirming that the connection with the repeater 6 via the Internet 4 has been established. Upon receiving the confirmation signal from management server 200 , relay device 6 transmits a response signal to the confirmation signal to management server 200 . When the management server 200 receives a response signal from the relay device 6, it determines YES in step S122, and the process proceeds to step S124. On the other hand, if the management server 200 does not receive the response signal from the repeater 6, it determines NO in step S122, and the process proceeds to S132. Note that, in a modified example, the management server 200 may be configured to periodically transmit a confirmation signal to the repeater 6 .

In step S124, the management server 200 determines whether the BT connection between the repeater 6 and the cooker 10 is currently established. In this embodiment, the management server 200 determines whether or not the elapsed time from the reception of the latest cooker information is equal to or longer than the second predetermined time. Determine whether a BT connection is currently established. The second predetermined time may be longer than the first predetermined time. Management server 200 determines YES in step S124 when the elapsed time since receiving the latest cooker information is less than the second predetermined time, and the process proceeds to step S130. On the other hand, management server 200 determines NO in step S124 when the elapsed time since receiving the latest cooker information is equal to or longer than the second predetermined time, and the process proceeds to step S132. Note that, in a modified example, management server 200 may receive information indicating whether or not the BT connection between relay device 6 and cooker 10 is established from relay device 6 .

In step S<b>130 , management server 200 transmits cooking appliance information in the memory of management server 200 to portable terminal 100 . When receiving the cooker information from the management server 200, the portable terminal 100 causes the display unit 102 to display a screen corresponding to the information in the cooker information. When the cooker information includes "power off" and battery voltage BV, the power off screen D1 (see FIG. 5(a)) is displayed on the display unit 102. FIG. On the power OFF screen D1, a message indicating that the power of the cooking device 10 is OFF and the battery voltage BV are displayed on the display unit 102 . Further, when the cooker information includes "power ON", the stopped screen D2 (see FIG. 5(b)) is displayed. A message indicating that the operation of the stove burner 12 and the grill burner 14 is being stopped is displayed on the in-stop screen D2. Further, when the cooker information includes “stove burner ON” or “grill ON”, the screen D3 during combustion (see FIG. 5(c)) is displayed on the display unit 102 . The burning screen D3 displays a message indicating that the stove burner 12 or grill burner 14 is in operation. In this way, the user of cooking device 10 can know the current operating state of cooking device 10 . After step S130 ends, the process returns to step S110.

Also, in step S<b>132 , the management server 200 transmits communication abnormality information to the mobile terminal 100 . When the mobile terminal 100 receives the communication abnormality information from the management server 200, the mobile terminal 100 causes the display unit 102 to display the communication abnormality screen D4 (see FIG. 5(d)). A message indicating a communication error is displayed on the communication error screen D4. After step S132 ends, the process returns to step S110.

(Specific case; Figure 6)
Next, a specific case realized by the processing of FIGS. 3 and 4 will be described. In the initial state of this case, the battery 52 is attached to the battery attachment portion 50 of the heating cooker 10, and the power of the heating cooker 10 is off. Therefore, power is supplied from the battery 52 to the BT module 30, and power supply from the battery 52 to the main control board 20 is stopped.

At T10, the user operates the power switch 16 to turn on the power of the cooker 10 . In this case, the power cutoff circuit 26 of the main control board 20 switches from the cutoff state to the supply state. Then, power supply from the battery 52 to the main control circuit 22 is started.

At T<b>12 , the user performs an ignition operation on the heating cooker 10 to ignite the stove burner 12 . In this case, the main control circuit 22 ignites the stove burner 12 .

When the first predetermined time has passed since the power source of the heating cooker 10 was turned on (YES in step S10 in FIG. 3), the BT control circuit 32 determines that power is being supplied to the main control board 20 at T20. It determines (YES in step S20) and supplies the status information request to the main control circuit 22. FIG.

At T20, when the main control circuit 22 acquires the state information request from the BT control circuit 32, it determines that the stove burner 12 is in combustion, and supplies state information including "stove burner ON" to the BT control circuit 32. .

When the BT control circuit 32 acquires the state information from the main control circuit 22 at T22 (step S22 in FIG. 3), at T30, the cooking appliance information is sent to the management server 200 via the BT communication circuit 42 and the repeater 6. Send. Also, the BT control circuit 32 transmits cooker information to the alarm device 90 at T32.

When the management server 200 receives the cooker information from the heating cooker 10 at T30, the management server 200 stores the cooker information in the memory of the management server 200 at T34.

Thereafter, at T40, the user performs an operation to turn off the right stove burner. In this case, the main control circuit 22 extinguishes the stove burner 12 at T42. Then, at T44, the user operates the power switch 16 to turn off the power of the cooking device 10. FIG. In this case, the power cutoff circuit 26 of the main control board 20 switches from the supply state to the cutoff state, and power supply from the battery 52 to the main control circuit 22 stops.

BT control circuit 32 determines that power is not supplied to main control board 20 when the first predetermined time elapses after transmission of cooking appliance information (YES in step S10 in FIG. 3) ( NO in step S20), the battery voltage BV is specified. Then, at T50, the BT control circuit 32 transmits cooker information including "power OFF" and battery voltage BV to the management server 200 via the BT communication circuit 42 and the repeater 6. FIG.

When the management server 200 receives the cooker information from the heating cooker 10 at T50, the management server 200 stores the cooker information in the memory of the management server 200 at T52.

As described above, power is supplied from the battery 52 to the BT module 30 regardless of whether the power cutoff circuit 26 of the main control board 20 is in the supply state or the cutoff state. That is, the BT module 30 is maintained in a state capable of communicating with external devices even when the power supply from the battery 52 to the main control board 20 is stopped. Therefore, even when the power supply from the battery 52 to the main control board 20 is stopped, the cooking device 10 can communicate with an external device using the BT module 30. . Also, power consumption when the BT module 30 operates is relatively small. Therefore, power consumption of the heating cooker 10 can be suppressed while maintaining a state in which communication with an external device using the BT module 30 can be performed.

Also, the BT module 30 transmits cooker information to the mobile terminal 100 regardless of the state of the power cutoff circuit 26 of the main control board 20 . Therefore, the user of the cooking device 10 can know the state of the cooking device 10 by checking the cooking device information transmitted to the portable terminal 100 even when the power cutoff circuit 26 is in the cutoff state.

In addition, when the power cutoff circuit 26 of the main control board 20 is in the supply state (YES in step S20 of FIG. 3), the BT module 30 sends the cooker information to a plurality of external devices (for example, the repeater 6, the alarm device 90, etc.). , to the mobile terminal 100). On the other hand, the BT module 30 transmits the cooker information only to the repeater 6 when the power cutoff circuit 26 is in the cutoff state (NO in step S20 of FIG. 3). Therefore, when the power cutoff circuit 26 is in the cutoff state, the power consumption of the heating cooker 10 can be suppressed compared to a configuration in which cooker information is transmitted to all of the plurality of external devices.

Cooking device 10 also operates with power supplied from battery 52 . With such a configuration, the battery 52 needs to be replaced when the power supplied from the battery 52 to the main control board 20 and the BT module 30 runs out. Frequent replacement of the battery 52 is troublesome for the user. As described above, power consumption when the BT module 30 operates is relatively small. Therefore, consumption of the battery 52 is suppressed when the power cutoff circuit 26 is cut off. Therefore, the replacement frequency of the battery 52 can be reduced, and the user's convenience can be improved.

In addition, when the power cutoff circuit 26 of the main control board 20 is in the cutoff state (NO in step S20 of FIG. 3), the BT module 30 detects the cooker information including the battery voltage BV measured by the battery voltage measurement circuit 38. is transmitted to the repeater 6 (step S30). Then, relay device 6 transmits the cooker information to management server 200 . In this case, the user of the heating cooker 10 can operate the portable terminal 100 to obtain the cooker information stored in the management server 200 and check the battery voltage BV in the cooker information. Therefore, the user of the heat cooker 10 can determine whether or not the battery 52 attached to the heat cooker 10 should be replaced. Therefore, the user of the heating cooker 10 can replace the battery 52 before the power supplied from the battery 52 to the main control board 20 and the BT module 30 becomes insufficient. As a result, it is possible to prevent the cooker 10 from operating due to insufficient power supplied from the battery 52 to the main control board 20 and the BT module 30 .

Also, the power consumed by a module capable of executing communication according to the BT system is smaller than the power consumed by a module capable of executing communication according to the Wi-Fi (registered trademark) system, for example. Therefore, power consumption of the heating cooker 10 can be suppressed while maintaining a state in which communication with an external device using the BT module 30 can be performed.

(correspondence relationship)
The heating cooker 10 is an example of a "thermal appliance." The main control circuit 22 and the BT module 30 are examples of the "main control section" and the "communication module", respectively. The power cutoff circuit 26 is an example of the "switching section". The first predetermined time is an example of the "predetermined cycle". The cooker information is an example of the "thermal appliance information." The repeater 6, the alarm device 90, and the mobile terminal 100 are examples of the "plurality of external devices." The repeater 6 is an example of "some specific external devices." The main voltage measuring circuit 36 and the battery voltage measuring circuit 38 are examples of the "first voltage measuring section" and the "second voltage measuring section", respectively. "Power ON" and "Power OFF" in the cooker information are examples of "first voltage-related information." The battery voltage BV in the cooker information is an example of "second voltage-related information."

Although each embodiment has been described in detail above, these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above.

(First Modification) The “heat device” is not limited to the heating cooker 10, and may be a dishwasher, a clothes dryer, or the like.

(Second Modification) The “communication module” is not limited to the BT module 30, and may be a wireless communication module such as a Wi-Fi module, or a wired communication module.

(Third Modification) The heating cooker 10 may not have the battery mounting portion 50 and may operate using a commercial power source as a power supply source. In this modified example, the commercial power supply is an example of the "power supply section".

(Fourth Modification) The BT control circuit 32 may transmit cooking appliance information to the repeater 6 and the alarm device 90 in step S30 of FIG. In addition, the BT control circuit 32 may also transmit the cooking appliance information to the mobile terminal 100 when the BT connection with the mobile terminal 100 is established.

(Fifth Modification) The BT control circuit 32 may transmit cooking appliance information including the main voltage MV and the battery voltage BV to the repeater 6 in step S30 of FIG. In this modification, the management server 200 stores cooker information including the main voltage MV and the battery voltage BV in step S112 of FIG. When management server 200 receives a request signal from mobile terminal 100 while the cooking appliance information is stored, management server 200 transmits cooking appliance information including main voltage MV and battery voltage BV to mobile terminal 100 . In this case, the display unit 102 of the mobile terminal 100 displays a screen including the main voltage MV and the battery voltage BV. Such a configuration also allows the user to know that the cooking device 10 is powered off. Further, in this modification, the BT control circuit 32 may transmit the cooker information including the main voltage MV and the state information to the repeater 6 and the alarm device 90 in step S24. In this modified example, the main voltage MV is an example of the "first voltage-related information."

(Sixth Modification) The BT control circuit 32 may determine whether or not the battery voltage BV is equal to or lower than the second predetermined voltage when NO is determined in step S20 of FIG. The second predetermined voltage is a threshold for determining whether battery 52 needs to be replaced. In this modification, when the BT control circuit 32 determines that the battery voltage BV is less than the second predetermined voltage, in step S30, the BT control circuit 32 turns off the power and the battery voltage BV is less than the second predetermined voltage. Cooker information including information indicating that is transmitted to the repeater 6 . Further, when the BT control circuit 32 determines that the battery voltage BV is equal to or higher than the second predetermined voltage, the BT control circuit 32 indicates "power OFF" and indicates that the battery voltage BV is equal to or higher than the second predetermined voltage in step S30. The cooker information containing the information is transmitted to the repeater 6 . In this case, a screen including information indicating that the battery voltage BV is less than the second predetermined voltage or information indicating that the battery voltage BV is equal to or higher than the second predetermined voltage is displayed on the display unit 102 of the mobile terminal 100. Is displayed. Such a configuration also allows the user to know whether or not the battery 52 needs to be replaced. In this modification, the information indicating that the battery voltage BV is less than the second predetermined voltage and the information indicating that the battery voltage BV is greater than or equal to the second predetermined voltage are examples of the "second voltage-related information." be.

(Sixth Modification) The heating cooker 10 may not include at least one of the main voltage measurement circuit 36 and the battery voltage measurement circuit 38 . In this modification, at least one of the "first voltage measurement section" and the "second voltage measurement section" can be omitted.

(Seventh Modification) The management server 200 is configured to transmit update program data for updating information (for example, a program) stored in the memory of the CPU 24 of the main control circuit 22 to the heating cooker 10. may In this modification, the BT control circuit 32 determines whether power is being supplied to the main control board 20 when receiving update program data from the management server 200 via the relay device 6 . When the BT control circuit 32 determines that power is being supplied to the main control board 20 , the BT control circuit 32 transmits update program data to the main control circuit 22 via the communication circuits 28 and 40 . The main control circuit 22 uses the received update program data to update the information in the memory of the CPU 24 . On the other hand, when the BT control circuit 32 determines that power is not being supplied to the main control board 20, it monitors whether the state of power supply to the main control board 20 is switched. Then, when the BT control circuit 32 determines that the state in which power is not supplied to the main control board 20 has switched to the state in which power is being supplied to the main control board 20, , to transmit update program data to the main control circuit 22 . The main control circuit 22 uses the received update program data to update the information in the memory of the CPU 24 . In this manner, even when power is not supplied to the main control board 20, the heating cooker 10 can receive the update program data from the management server 200. Information in memory can be updated.

The technical elements described in this specification or in the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims as of the filing. In addition, the techniques exemplified in this specification or drawings can simultaneously achieve a plurality of purposes, and achieving one of them has technical utility in itself.

2: Cooking system 4: Internet 6: Repeater 10: Heating cooker 12: Stove burner 14: Grill burner 16: Power switch 20: Main control board 22: Main control circuit 24: CPU
26: Power cutoff circuit 28: Communication circuit 30: BT module 32: BT control circuit 34: CPU
36 : Main voltage measuring circuit 38 : Battery voltage measuring circuit 40 : Communication circuit 42 : BT communication circuit 50 : Battery mounting unit 52 : Battery 90 : Alarm device 92 : Notification means 100 : Mobile terminal 102 : Display unit 104 : Operation unit 106 : BT communication circuit 108 : Wi-Fi communication circuit 110 : Terminal control circuit 112 : CPU
114: Memory 116: Cooker application 200: Management server

Claims (5)

a thermal appliance,
a main control unit connected to a power supply unit and controlling the operation of the thermal equipment;
a communication module connected to the power supply unit and capable of communicating with a plurality of external devices;
A supply state in which power is supplied from the power supply unit to the main control unit and a power supply state in which power supply from the power supply unit to the main control unit is stopped is provided between the main control unit and the power supply unit. a switching unit capable of switching between a cut-off state and
with
Power is always supplied to the communication module from the power supply unit ,
The communication module is
transmitting thermal equipment information about the thermal equipment to a plurality of external devices at predetermined intervals when the switching unit is in the supply state;
A thermal device, wherein the thermal device information is transmitted to a specified external device among the plurality of external devices at each predetermined cycle when the switching unit is in the cut-off state. The thermal equipment further comprises a first voltage measurement unit that measures a voltage value supplied to the main control unit,
2. The thermal equipment according to claim 1 , wherein said thermal equipment information includes first voltage relation information related to a voltage value supplied to said main control unit measured by said first voltage measuring unit. 3. Thermal equipment according to claim 1 or 2 , further comprising the power supply unit comprising a battery. The thermal equipment further comprises a second voltage measuring unit that measures the voltage value of the battery,
4. The thermal equipment according to claim 3 , wherein said thermal equipment information includes second voltage-related information related to the voltage value of said battery measured by said second voltage measuring unit. A thermal equipment system comprising a thermal equipment and a plurality of external devices,
The thermal equipment includes:
a main control unit connected to a power supply unit and controlling the operation of the thermal equipment;
a communication module connected to the power supply unit and capable of communicating with the plurality of external devices;
A supply state in which power is supplied from the power supply unit to the main control unit and a power supply state in which power supply from the power supply unit to the main control unit is stopped is provided between the main control unit and the power supply unit. and a switching unit capable of switching between a cut-off state,
Power is always supplied to the communication module from the power supply unit,
The communication module is
transmitting thermal equipment information about the thermal equipment to the plurality of external devices at predetermined intervals when the switching unit is in the supply state;
A thermal equipment system, wherein the thermal equipment information is transmitted to some specific external equipment among the plurality of external equipment in each of the predetermined cycles when the switching unit is in the cut-off state.

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