JP2020159624A - Gas heat source system - Google Patents

Abstract

To provide a technology capable of easily identifying a cause of disabling communication between a gas heat source device and a communication device.SOLUTION: The gas heat source device includes a first communication device configured to periodically transmit a communication signal while a power source supplies power. The communication device includes a second communication unit configured to receive the communication signal, a memory configured to store the history of the received communication signal, and a first control unit configured, when the communication signal is not periodically received in the second communication unit, to specify the cause of the stop of the periodical transmission of the communication signal.SELECTED DRAWING: Figure 1

Description

The techniques disclosed herein relate to gas heat source systems that utilize gas heat sources.

Patent Document 1 discloses a cooking cooker having a function of wirelessly transmitting and receiving an operating state of a gas stove, recipe data, and the like to and from a mobile terminal. When the power of the cooking cooker is turned off, the above-mentioned transmission / reception function is stopped, and communication with the mobile terminal becomes impossible. The power of the cooker is automatically turned off, for example, to save power.

JP-A-2018-40515

Communication with the above-mentioned mobile terminal may be impossible due to a cause other than turning off the power of the cooking cooker, for example, a failure of the wireless communication unit of the cooking cooker. When communication between the cooker and the mobile terminal becomes impossible, for example, it is necessary for the user to actually investigate the cooker in order to identify the cause.

The present specification provides a technique for easily identifying the cause of the inability to communicate between a gas heat source device and a communication device.

The gas heat source system disclosed in the present specification includes a gas heat source device that utilizes the gas heat source and a communication device that can communicate with the gas heat source device. The gas heat source device includes a power supply unit and a first communication unit configured to periodically transmit a notification signal while power is being supplied from the power supply unit. , A second communication unit configured to receive the notification signal transmitted by the first communication unit, and a history of the notification signal periodically received by the second communication unit are stored. When the notification signal is not periodically received by the configured memory and the second communication unit, the history in the memory is used to cause the periodic transmission of the notification signal to be stopped. A first control unit, which is configured to specify the above.

According to the above configuration, the gas heat source device periodically transmits a notification signal. On the other hand, the communication device stores the history of the notification signal received periodically in the memory. Then, when the notification signal is not received periodically, the communication device uses the history in the memory to identify the cause of the stop of the periodic transmission of the notification signal. As a result, the cause of the inability to communicate between the gas heat source device and the communication device can be easily identified.

The first control unit is configured to identify the cause of the periodic stoppage of transmission of the notification signal from among a plurality of causes, and the plurality of causes are the supply of electric power from the power supply unit to the first communication unit. Has stopped, and an abnormality has occurred that prevents communication between the first communication unit and the second communication unit while the power supply from the power supply unit to the first communication unit continues. May include.

According to the above configuration, the communication device causes, for example, the power supply to the first communication unit to be stopped or an abnormality in which communication is not possible to occur as the cause of the stop of the periodic transmission of the notification signal. Can be identified.

The notification signal includes status information indicating the status of the gas heat source device, and the first control unit notifies the user of the status indicated by the status information included in the notification signal periodically received by the second communication unit. It may be configured in.

According to the above configuration, the notification signal can be used to notify the user of the status of the gas heat source device.

When the state information included in the latest notification signal in the history indicates a predetermined state in which the process of turning off the power of the gas heat source device is started, the first control unit notifies from among a plurality of causes. It is identified that the power supply from the power supply unit to the first communication unit has stopped as the cause of the suspension of periodic signal transmission, and the status information included in the latest notification signal in the history is a predetermined status. When indicating a state different from the above, it may be specified that an abnormality in which communication is not possible has occurred as a cause of stopping the periodic transmission of the notification signal from among a plurality of causes.

According to the above configuration, the cause of the suspension of periodic transmission of the notification signal can be identified by using the notification signal for notifying the user of the state of the gas heat source device.

The gas heat source device further includes a second control unit, and the second control unit connects the first communication unit and the second communication unit when an instruction to turn on the power of the gas heat source device is given to the gas heat source device. When communication for establishing a wireless connection between them is attempted with the second communication unit and the establishment of the wireless connection fails as a result of the communication, communication between the first communication unit and the second communication unit is impossible. It may be configured to notify the user that an abnormality has occurred.

When the instruction to turn on the power of the gas heat source device is given to the gas heat source device, the transmission of the notification signal has not been started because the power has not yet been supplied to the first communication unit. According to the above configuration, if an abnormality in which communication is not possible occurs before the transmission of the notification signal is started, it is possible to notify the user that the abnormality in which communication is not possible has occurred.

It is a figure which shows typically the structure of a gas heat source system. It is a flowchart which shows the monitoring process of a repeater. It is a figure which shows the specific case realized by a gas heat source system. It is a figure which shows the specific case X1. It is a figure which shows the specific case X2. This is a specific example of each screen displayed on the mobile terminal. It is a flowchart which shows the initial judgment process of a cooking apparatus.

(First Example)
(Gas heat source system 2; Fig. 1)
The gas heat source system 2 of the first embodiment will be described with reference to the drawings. The gas heat source system 2 includes a heating cooker 10, a repeater 100, an access point 200 (hereinafter, referred to as “AP (abbreviation of Access Point) 200”), a server 300, and a mobile terminal 400. The mobile terminal 400 can communicate with the server 300 via the Internet 6.

The AP200 can form a wireless LAN (Local Area Network) according to the Wi-Fi (registered trademark) method. The repeater 100 participates in the wireless LAN formed by the AP200. The AP200 is also connected to the Internet 6. As a result, the repeater 100 can communicate with the server 300 via the AP 200 and the Internet 6. In the modified example, the repeater 100 may participate in the wired LAN.

The repeater 100 is a device for relaying communication between the cooking cooker 10 and the server 300. The repeater 100 can communicate with the cooking cooker 10 by using wireless communication (hereinafter, referred to as “BT communication”) according to the Bluetooth (registered trademark) method. Further, as described above, the repeater 100 can communicate with the server 300 via the AP200. As a result, the cooking cooker 10 can communicate with the server 300 via the repeater 100, the AP200, and the Internet 6.

(Structure of cooking cooker 10)
The cooking cooker 10 is a gas combustion type stove. The cooking cooker 10 includes a stove burner 12, an operation unit 14, a display unit 15, a BT interface 16, a power supply unit 18, a power supply switch 20, and a control unit 30. In the following, the interface may be referred to as "I / F".

The stove burner 12 is a burner for heating a heating target (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 the gas is being supplied to the stove burner 12. For example, the cooker 10 has three stove burners 12.

The operation unit 14 is an operation unit for igniting, extinguishing, and adjusting the heating amount of the stove burner 12. The display unit 15 is a display for displaying various information. The display unit 15 may function as a so-called touch panel (that is, an operation unit 14). The BTI / F16 is a communication interface for executing BT communication with an external device (for example, the repeater 100).

The power supply unit 18 is a battery that supplies electric power to each unit (for example, 16 and 30) of the cooking cooker 10. In the modified example, the power supply unit 18 may be a commercial power supply.

The power switch 20 is a switch for receiving an instruction to turn on the power of the cooking cooker 10 and an instruction to turn off the power. When an instruction to turn on the power is given to the power switch 20, power is supplied from the power supply unit 18 to each part of the cooking cooker 10 (for example, BTI / F16, control unit 30). When an instruction to turn off the power is given to the power switch 20, the power supply from the power supply unit 18 to each part of the cooking cooker 10 (for example, BTI / F16, control unit 30) is cut off. It can be seen that the power was turned off because the power supply to the BTI / F16 was cut off.

The control unit 30 includes a memory 32 composed of a volatile memory, a non-volatile memory, and the like. The control unit 30 controls the operation of each unit (for example, 12 to 20) of the cooking cooker 10 according to the program 34 stored in the memory 32.

For example, the control unit 30 starts the power-off process when the power switch 20 is instructed to turn off the power. The power OFF process is a process of cutting off the supply of electric power from the power supply unit 18 to each unit of the cooking cooker 10. Further, the control unit 30 automatically turns off the power when a long period of time (for example, 1 hour) has elapsed since the last operation of the operation unit 14 in the state where the power of the cooking cooker 10 is turned on. Start processing. As a result, it is possible to prevent the power supply unit 18 from being wasted.

Further, for example, when the power of the cooking cooker 10 is turned on, the control unit 30 periodically (for example, every 10 seconds) supplies a command to broadcast a notification signal to the BTI / F 16. As a result, the BTI / F 16 periodically broadcasts the notification signal while the power is being supplied from the power supply unit 18. The notification signal is a signal for notifying the user of the state of the gas heat source device. The notification signal includes status information indicating the status of the gas heat source device. The state of the gas heat source device is one of a plurality of states including "combustion", "stop", and "power off". Here, "combustion" is a state in which the stove burner 12 is ignited in a situation where the cooking device 10 is turned on. "Stop" is a state in which the stove burner 12 is extinguished in a situation where the cooking device 10 is turned on. "Power off" is a state in which the power off process is started.

The notification signal is, for example, an Advanced signal according to the Bluetooth method. The Advantage signal is a signal that can be broadcast and transmitted, in other words, without establishing a wireless connection for unicast communication between the BTI / F16 and another BTI / F (eg, 116). It is a signal that can be transmitted to the BTI / F of.

(Configuration of repeater 100)
The repeater 100 includes a BTI / F116, a wireless LANI / F122, and a control unit 130. The BTI / F116 is a communication interface for executing BT communication with the cooking cooker 10. The wireless LAN I / F 122 is a communication interface for executing wireless LAN communication with the AP200.

The control unit 130 includes a memory 132 composed of a volatile memory, a non-volatile memory, and the like. The control unit 130 controls the operations of the units 116 and 122 of the repeater 100 according to the program 134 stored in the memory 132. For example, the control unit 130 supplies the wireless LANI / F 122 with an instruction to transmit the state information included in the notification signal received from the cooking cooker 10 to the server 300 according to the program 134.

In addition, the memory 132 can store the history information 136. The history information 136 is information indicating the history of the notification signal periodically received from the BTI / F16 of the cooking cooker 10 by the BTI / F116. The history information 136 is information that is temporarily stored while the notification signal is periodically received. Specifically, the history information 136 is generated when the cooking cooker 10 starts periodically transmitting a notification signal. Then, the history information 136 is determined when the cooking cooker 10 ends the periodic transmission of the notification signal (for example, after receiving the notification signal including the state information indicating "power off" from the cooking cooker 10). When time (for example, 1 minute) elapses), it is erased from the memory 132. The above-mentioned predetermined time is set to be longer than the cycle in which the notification signal is periodically transmitted.

(Configuration of server 300)
The server 300 is a server provided by the vendor of the cooker 10. The server 300 receives the state information of the cooking device 10 from the repeater 100 and stores the state information.

(Configuration of mobile terminal 400)
The mobile terminal 400 is, for example, a portable terminal such as a smartphone, a tablet terminal, or a notebook PC. The application program 410 provided by the vendor of the cooker 10 is installed in the mobile terminal 400. The mobile terminal 400 receives the state information stored in the server 300 by accessing the server 300 according to the application program 410, and displays a screen showing the state of the cooking cooker 10 indicated by the state information. As a result, the user can know the state of the cooking cooker 10 even if he / she is not near the cooking cooker 10.

(Monitoring process; Fig. 2)
A monitoring process executed by the control unit 130 of the repeater 100 according to the program 134 will be described with reference to FIG. The monitoring process is started with the power of the repeater 100 being turned on as a trigger.

In S10, the control unit 130 monitors that the notification signal is periodically (that is, at a predetermined cycle) received from the cooking device 10 via the BTI / F116. Specifically, when the control unit 130 receives the notification signal in a state where the history information 136 is not stored in the memory 132, the control unit 130 determines that the notification signal has been received periodically (YES in S10). Proceed to S12. Further, when the control unit 130 receives the notification signal before and then receives the notification signal again at a predetermined cycle, the control unit 130 determines that the notification signal has been received periodically (YES in S10), and proceeds to S12. .. On the other hand, if the control unit 130 does not receive the notification signal again in a predetermined cycle after receiving the notification signal before, the control unit 130 determines that the notification signal is not received periodically (NO in S10), and S30. Proceed to.

In S12, the control unit 130 stores the notification signal received from the cooking cooker 10 as the history information 136.

In S14, the control unit 130 identifies the latest notification signal (that is, the notification signal received in S10) and the notification signal immediately before the latest notification signal from the history information 136. Then, the control unit 130 determines whether or not the state indicated by the state information included in the latest notification signal has changed from the state indicated by the state information included in the previous notification signal. When the control unit 130 determines that the latest state has changed from the previous state (YES in S14), the control unit 130 proceeds to S16. On the other hand, when the control unit 130 determines that the latest state is the same as the previous state (NO in S14), the control unit 130 returns to S10. If only one notification signal is specified from the history information 136, the control unit 130 determines YES and proceeds to S16.

In S16, the control unit 130 determines the state information in the latest notification signal identified in S14 as transmission information. The transmission information is information transmitted to the server 300. When S16 is completed, the process proceeds to S40.

In S40, the control unit 130 transmits the transmission information determined in S16 to the server 300 via the wireless LANI / F122. When S40 is completed, the process returns to S10.

Further, when the control unit 130 determines that the notification signal has not been received periodically (NO in S10), the control unit 130 determines in S30 that the latest notification signal from the history information 136 (that is, the notification received in the previous cycle). Signal). Then, the control unit 130 determines whether or not the state information included in the specified notification signal indicates "power off".

When the control unit 130 determines that the latest state indicates "power off" (YES in S30), the control unit 130 determines in S32 the state information indicating "power off" as transmission information. On the other hand, when the control unit 130 determines that the latest state indicates a state other than "power off" (that is, "combustion" or "stop") (NO in S30), the control unit 130 outputs information indicating "communication abnormality". Determined as transmission information. When the processing of S30 or S32 is completed, the process proceeds to S40. As a result, in S40, the control unit 130 transmits the transmission information indicating "power off" or the transmission information indicating "communication abnormality" to the server 300.

(Specific case; Fig. 3, Fig. 4, Fig. 5)
A specific case realized by the monitoring process of FIG. 2 will be described with reference to FIGS. 3, 4, and 5. In the following, for ease of understanding, the operation executed by the control unit (for example, the control unit 30) of each device is not described mainly for the control unit, but for each device (for example, the cooking cooker 10). ) Is mainly described.

At T10, the user operates the power switch 20 to give an instruction to turn on the power to the cooking cooker 10. As a result, power is supplied from the power supply unit 18 to the BTI / F16.

In this case, the stove burner 12 is extinguished at this time. Therefore, in T12, the cooking cooker 10 broadcasts the notification signal A1 including the state information "stop" via the BTI / F16.

In this case, the memory 132 does not store the history information 136 at this time. Therefore, when the repeater 100 receives the notification signal A1 including the state information "stop" from the cooking cooker 10 via the BTI / F116 in the T12, it determines that the notification signal has been periodically received ( YES in S10), in T14, the notification signal A1 is stored as history information 136.

In T16, since the repeater 100 identifies only one notification signal A1 from the history information 136 (YES in S14), the state information “stop” in the notification signal A1 is determined as transmission information (S16).

At T18, the repeater 100 transmits the transmission information “stop” to the server 300 via the wireless LANI / F122 (S40). As a result, the server 300 stores the transmission information "stop" (that is, the state information "stop") at T20.

Subsequently, a predetermined cycle P (for example, 10 seconds) elapses from the time point of T12. At this point, the stove burner 12 is still extinguished. Therefore, in T32, the cooking cooker 10 broadcasts the notification signal A2 including the state information "stop" in the same manner as in T12.

When the repeater 100 receives the notification signal A2 including the state information "stop" at T32, it determines that the notification signal has been received periodically (YES in S10), and at T14, transmits the notification signal A2 to the history information 136. Is memorized as (S14). Here, since the status information in the notification signal A1 and the notification signal A2 in the history information 136 has not changed (NO in S14), the repeater 100 does not transmit the transmission information to the server 300, and the next Wait for the notification signal to be received.

Subsequently, in T40, the user operates the operation unit 14 to ignite the stove burner 12. Then, a predetermined cycle P elapses from the time point of T32. At this point, the stove burner 12 is igniting. Therefore, the cooking cooker 10 broadcasts the notification signal B1 including the state information "combustion" at T42.

When the repeater 100 receives the notification signal B1 including the state information "combustion" at T42 (YES in S10), the repeater 100 stores the notification signal B1 as history information 136 at T44 (S14).

In T46, the repeater 100 identifies the latest notification signal B1 and the previous notification signal A2 from the history information 136. Then, the repeater 100 determines that the state information "combustion" in the latest notification signal B1 has changed from the state information "stop" in the previous notification signal A2 (YES in S14). The state information "combustion" in the notification signal B1 is determined as transmission information (S16). The T48 is similar to the T18, except that the transmitted information is the state information "burning". The T50 is the same as the T20 except that the state information "combustion" is stored.

Subsequently, the user operates the operation unit 14 to repeat ignition and extinguishing. As a result, for example, the repeater 100 stores the history information 136 including the notification signals A1 to C1.

(Case X1; Fig. 4)
In this case, it is assumed that a long period of time (for example, 1 hour) has passed since the operation unit 14 was last operated. The date and time when the notification signal C1 is transmitted is immediately before the elapse of the long time. At T60, the cooking cooker 10 automatically starts the power-off process. When the power OFF process is started, the cooker 10 enters the state information in a predetermined cycle P via the BTI / F16 before cutting off the power supply from the power supply unit 18 to the BTI / F16 in the T62. A notification signal D1 including "power off" is transmitted to the repeater 100. Then, the cooking cooker 10 cuts off the supply of electric power from the power supply unit 18 to the BTI / F16 at T63, and ends the power-off process.

When the repeater 100 receives the notification signal D1 including the state information "power OFF" in T62 (YES in S10), the repeater 100 stores the notification signal D1 as history information 136 in T64 (S14).

In T66, the repeater 100 identifies the latest notification signal D1 and the previous notification signal C1 from the history information 136. Then, the repeater 100 determines that the state information "power OFF" in the latest notification signal D1 has changed from the state information "stop" in the previous notification signal C1 (YES in S14). , The state information "power OFF" in the notification signal D1 is determined as transmission information (S16). T68 is the same as T18 in FIG. 3, except that the transmission information is the state information “power off”. The T70 is the same as the T20 in FIG. 3, except that the state information “power OFF” is stored.

As mentioned above, the power supply to the BTI / F16 has already been cut off. Therefore, the cooking cooker 10 does not transmit the notification signal to the repeater 100 even after the predetermined cycle P has elapsed from the time of T62. As a result, the repeater 100 determines at T72 that the notification signal has not been received periodically (NO in S10).

In T74, the repeater 100 identifies the latest notification signal D1 from the history information 136, and determines that the state information in the identified notification signal D1 indicates "power off" (YES in S30).

In T76, the repeater 100 determines the state information "power OFF" in the notification signal D1 as transmission information (S32). T78 and T80 are the same as T68 and T70. That is, the repeater 100 notifies the server 300 that the cause of the stop of the periodic transmission of the notification signal is the power OFF process.

(Case X2; Fig. 5)
In this case, it is assumed that an abnormality in which communication is not possible occurs between the BTI / F16 and the BTI / F116 while the power of the cooking cooker 10 is ON. For example, when the BTI / F16 fails or the like, the above-mentioned abnormality in which communication is impossible occurs. The date and time when the above notification signal C1 is transmitted is immediately before an abnormality in which communication is not possible occurs. Due to the occurrence of an abnormality in which communication is not possible, the notification signal is not received by the repeater 100 even if a predetermined cycle P has elapsed from the time when the notification signal C1 is transmitted. As a result, the repeater 100 determines in T102 that the notification signal has not been received periodically (NO in S10).

In T104, the repeater 100 identifies the latest notification signal C1 from the history information 136, and determines that the status information in the identified notification signal C1 indicates "stop" (NO in S30).

In T106, the repeater 100 determines the state information "communication abnormality" as transmission information (S34). T108 is the same as T18 in FIG. 3, except that the transmission information is the state information “communication abnormality”. The T110 is the same as the T20 in FIG. 3, except that the state information “communication abnormality” is stored. That is, the repeater 100 notifies the server 300 that the cause of the suspension of periodic transmission of the notification signal is the occurrence of a state in which communication is not possible.

(Each screen of the mobile terminal; Fig. 6)
With reference to FIG. 6, each screen displayed on the mobile terminal 400 by accessing the server 300 will be described. When the server 300 is accessed from the mobile terminal 400, the server 300 transmits the currently stored state information to the mobile terminal 400. As a result, the mobile terminal 400 displays the screens SC1 to SC4 showing the current state of the cooking cooker 10 according to the state information received from the server 300. The screens SC1 to SC4 can notify the user of the current state of the cooker 10.

For example, when the state of the cooking cooker 10 is "stopped" (for example, when accessed by T20 in FIG. 3), the mobile terminal 400 displays the screen SC1 (FIG. 6A). The screen SC1 contains a message indicating that the cooker 10 (ie, the stove burner 12) is stopped. Further, for example, when the state of the cooking cooker 10 is "combustion" (for example, when accessed by T50 in FIG. 3), the mobile terminal 400 displays the screen SC2 (FIG. 6 (b)). The screen SC2 contains a message indicating that the cooker 10 (ie, the stove burner 12) is burning. Further, for example, when the state of the cooking cooker 10 is "power off" (that is, when it is accessed by T70 or T80 in FIG. 4), the mobile terminal 400 displays the screen SC3 (FIG. 6 (c)). To do. The screen SC3 includes a message indicating that the power of the cooking cooker 10 is OFF. Further, for example, when the state of the cooking cooker 10 is "communication abnormality" (that is, when it is accessed by T110 of FIG. 5), the mobile terminal 400 displays the screen SC4 (FIG. 6 (d)). The screen SC4 includes a message indicating that an abnormality in which communication is not possible has occurred between the cooking cooker 10 and the repeater 100.

(Initial judgment process; Fig. 7)
With reference to FIG. 7, the initial determination process executed by the control unit 30 of the cooking cooker 10 according to the program 34 will be described. The initial determination process is started when an instruction to turn on the power is given to the power switch 20 as a trigger.

In S50, the control unit 30 starts supplying electric power from the power supply unit 18 to each part of the cooking cooker 10.

In S52, the control unit 30 attempts communication with the repeater 100 to establish a wireless connection for unicast communication. Specifically, the control unit 30 transmits an Advance signal for establishing a connection via the BTI / F16. Then, when the connection request is received from the repeater 100 as a response to the unicast signal, the control unit 30 executes communication of various signals for connection (for example, authentication communication) with the repeater 100, and the repeater 100. Successful establishment of wireless connection for unicast communication with. On the other hand, for example, when the connection request is not received from the repeater 100 as a response to the Advantage signal due to a failure of the BTI / F16 or the like, the establishment of the wireless connection fails. The control unit 30 skips S54 when the establishment of the wireless connection is successful (YES in S52), ends the process of FIG. 7, and fails in the establishment of the wireless connection (NO in S52), S54. Proceed to.

In S54, the control unit 30 displays an error screen on the display unit 15 indicating that an abnormality in which communication is not possible has occurred between the cooking cooker 10 and the repeater 100. As a result, it is possible to notify the user that an abnormality in which communication is not possible has occurred. In the modified example, the control unit 30 may prohibit the combustion of the cooking device 10. When S54 ends, the process of FIG. 7 ends.

When an instruction to turn on the power is given to the power switch 20, the notification signal is not periodically transmitted because the power has not yet been supplied to the BTI / F16. By executing the process of FIG. 7, it is possible to notify the user that an abnormality in which communication is not possible has occurred even before the periodic transmission of the notification signal is started.

(Effect of this example)
According to the configuration of this embodiment, the cooking cooker 10 periodically broadcasts a notification signal (T12, T32, T42, etc. in FIG. 3). Then, the repeater 100 stores history information 136 indicating the history of the notification signal that is periodically received (T14, T34, T44, etc.). Then, when the notification signal is not received periodically (T72 in FIG. 4 or T102 in FIG. 5), the repeater 100 uses the history information 136 to periodically select the notification signal from among a plurality of causes. Identify the cause of the stoppage of transmission. For example, in the repeater 100, when the latest state information of the history information 136 indicates "power off" (T74 in FIG. 4), the cause of the stop of periodic transmission of the notification signal is the power off process. (T76). Further, for example, when the latest state information in the history information 136 indicates "stop" which is a state other than "power off" (T104 in FIG. 5), the repeater 100 periodically transmits a notification signal. The cause of the suspension is identified as the occurrence of an abnormality in which communication is not possible (T106). That is, by using the history information 136, it is possible to identify the cause of the suspension of periodic transmission of the notification signal, and as a result, communication between the cooking cooker 10 and the repeater 100 becomes impossible. The cause can be easily identified.

(Correspondence)
The gas heat source system 2 is an example of a “gas heat source system”. The cooking cooker 10, the power supply unit 18, and the control unit 30 are examples of a “gas heat source device”, a “power supply unit”, and a “second control unit”, respectively. The control unit 30 that controls the BTI / F16 and the BTI / F16 is an example of the “first communication unit”. The repeater 100, the control unit 130, the memory 132, and the history information 136 are examples of the “communication device”, the “first control unit”, the “memory”, and the “history”, respectively. The control unit 130 that controls BTI / F116 and BTI / F116 is an example of the “second communication unit”. The state indicated by the state information "power OFF" is an example of the "predetermined state". The state indicated by the state information "stop" is an example of "different state". The process of S30 in FIG. 2 is an example of "identifying the cause of the stop of periodic transmission of the notification signal".

Although each embodiment has been described in detail above, these are merely examples and do not limit the scope of claims. The techniques described in the claims include various modifications and modifications of the specific examples illustrated above. Modifications of each of the above embodiments are listed below.

(Modification example 1) The "gas heat source device" is not limited to the heating cooker 10, and operates, for example, a gas fan heater, a dishwasher using a gas heat source, a water heater using a gas heat source, and the water heater. It may be a kitchen remote controller for doing so. Generally speaking, a "gas heat source device" is a device that uses gas.

(Modification 2) The gas heat source system 2 does not have to include the server 300 and the mobile terminal 400. In this case, the repeater 100 may be a mobile terminal, a stationary PC, or the like, and the repeater 100 may notify the state of the cooking cooker 10. Then, the latest notification signal (that is, the latest state information) may be stored in the repeater 100, and the repeater 100 may notify the cause of the communication failure. In this modification, a mobile terminal, a stationary PC, or the like is an example of a “communication device”. In another example, the gas heat source system 2 does not have to include the server 300. In this case, the repeater 100 may transmit the transmission information (that is, the latest state information) to the terminal device (for example, 400) in S40 of FIG. 2, and the transmission information is stored in the terminal device and communication is not performed. The possible cause may be notified by the terminal device. In another example, the repeater 100 may not include the control unit 130, and the server 300 may include the control unit 130. That is, the repeater 100 only relays the notification signal between the cooking cooker 10 and the server 300, and the server 300 may execute the monitoring process of FIG. According to this modification, the system including the repeater 100 and the server 300 is an example of the "communication device", and the control unit 130 provided in the server 300 is an example of the "memory" and the "first control unit". is there.

(Modification 3) The "first communication unit (and second communication unit)" is not limited to the BTI / F, and is, for example, a communication interface for executing wireless communication according to the Zigbee (registered trademark) method and a communication interface thereof. It may be a control unit that controls.

(Modification 4) The "notification signal" does not have to include the state information. For example, the notification signal may include a value "1" when the cooking device 10 is turned on, and may include a value "0" when the power OFF process is started. Then, instead of S30 to S40 in FIG. 2, the repeater 100 sets the latest notification signal in the history information 136 as a value when it is determined that the notification signal is not periodically received (YES in S10). It may be judged whether or not it contains "0". Then, when the repeater 100 determines that the latest notification signal includes the value "0", the repeater 100 notifies the user of "power off" as a cause of stopping the periodic transmission of the notification signal, and the latest notification signal. When it is determined that the value includes the value "1", the user may be notified of "communication abnormality" as a cause of stopping the periodic transmission of the notification signal. That is, in this modification, the state of the gas heat source device does not have to be notified to the user.

(Modification 5) The process of FIG. 7 does not have to be executed. In this modification, the "second control unit" can be omitted.

2: Gas heat source system 6: Internet 10: Cooking cooker 12: Stove burner 14: Operation unit 15: Display unit 16: BTI / F
18: Power supply unit 20: Power supply switch 30: Control unit 32: Memory 34: Program 100: Repeater 116: BTI / F
122: Wireless LAN I / F
130: Control unit 132: Memory 134: Program 136: History information 200: AP
300: Server 400: Mobile terminal 410: Application program

Claims (5)

A gas heat source system including a gas heat source device that uses a gas heat source and a communication device that can communicate with the gas heat source device.
The gas heat source device is
Power supply and
A first communication unit configured to periodically transmit a notification signal while power is being supplied from the power supply unit.
With
The communication device is
A second communication unit configured to receive the notification signal transmitted by the first communication unit, and
A memory configured to store the history of the notification signal periodically received by the second communication unit, and
When the notification signal is not received periodically by the second communication unit, the history in the memory is used to identify the cause of the suspension of periodic transmission of the notification signal. 1st control unit and
A gas heat source system. The first control unit is configured to identify the cause of the stop of periodic transmission of the notification signal from a plurality of causes.
The plurality of causes are the above, in a state where the power supply from the power supply unit to the first communication unit is stopped and the power supply from the power supply unit to the first communication unit is continued. The gas heat source system according to claim 1, wherein an abnormality in which communication is not possible has occurred between the first communication unit and the second communication unit. The notification signal includes state information indicating the state of the gas heat source device.
The first control unit is configured to notify the user of the state of the gas heat source device indicated by the state information included in the notification signal periodically received by the second communication unit. Item 2. The gas heat source system according to item 2. The first control unit
When the state information included in the latest notification signal in the history indicates a predetermined state in which the process of turning off the power of the gas heat source device is started, the notification is selected from the plurality of causes. It was identified that the power supply from the power supply unit to the first communication unit was stopped as the cause of the stoppage of periodic signal transmission.
When the state information included in the latest notification signal in the history indicates a state different from the predetermined state, the periodic transmission of the notification signal is stopped from among the plurality of causes. Identify that the communication impossible abnormality has occurred as the cause,
The gas heat source system according to claim 3. The gas heat source device further includes a second control unit.
The second control unit
When an instruction to turn on the power of the gas heat source device is given to the gas heat source device, the second communication unit performs communication for establishing a wireless connection between the first communication unit and the second communication unit. And try
When the establishment of the wireless connection fails as a result of the communication, the user is notified that an abnormality in which communication is not possible has occurred between the first communication unit and the second communication unit. The gas heat source system according to any one of claims 1 to 4, which is configured.

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