JP2019027622A - Communication system - Google Patents

Abstract

To provide a technique for enabling a thermal apparatus to surely use power related information corresponding to an electric power company with which a user using the thermal apparatus concludes a contract.SOLUTION: A communication system includes a thermal apparatus and a terminal device. The thermal apparatus is provided with a control device for controlling operation of the thermal apparatus. The terminal device displays an electric power company selection screen for selecting a specific electric power company with which a user using the thermal apparatus concludes a contract in a display part among a plurality of electric power companies, and transmits specific power related information corresponding to the specific electric power company to the thermal apparatus when the user selects the specific electric power company. The control device of the thermal apparatus receives the specific power related information from the terminal device, and controls operation of the thermal apparatus by using the specific power related information.SELECTED DRAWING: Figure 4

Description

  The technology disclosed in this specification relates to a communication system.

  Patent Document 1 discloses a thermal apparatus including a control device. A control apparatus memorize | stores the electric power relevant information corresponding to the specific electric power company with which the user using a thermal appliance has concluded the contract. The control device controls the operation of the thermal equipment using specific power related information.

JP 2014-206288 A

  A user who uses a thermal device selects a specific power company from a plurality of power companies and concludes a contract with the specific power company. Power-related information differs for each power company. Moreover, the electric power company with which a user concludes a contract may be changed. In the thermal device of Patent Literature 1, even after the power company that concludes the contract is changed by the user, specific power related information corresponding to the power company before the contract change is stored. In this case, the control device for the thermal equipment controls the operation of the thermal equipment using power related information different from the actual power related information.

  In the present specification, a technology is provided that allows a thermal device to reliably use power-related information corresponding to an electric power company with which a user using the thermal device has a contract.

  The communication system disclosed in the present specification includes a thermal device and a terminal device. The thermal device includes a control device that controls the operation of the thermal device. The terminal device displays, on the display unit, a power company selection screen for selecting a specific power company for which a user using the thermal equipment has signed a contract from among a plurality of power companies. When the specific power company is selected, specific power related information corresponding to the specific power company is transmitted to the thermal device. The control device for the thermal equipment receives the specific power related information from the terminal device, and controls the operation of the thermal equipment using the specific power related information.

  According to said structure, a terminal device displays an electric power company selection screen on a display part. Therefore, a user who uses a thermal device can select a specific power company with which the user has a contract from among a plurality of power companies. And a terminal device transmits the specific electric power relevant information corresponding to a specific electric power company to a thermal apparatus. Therefore, the control device for the thermal equipment can appropriately control the operation of the thermal equipment by using the specific power related information corresponding to the specific power company with which the user has a power contract.

  Further, when the user changes the power company with which the contract is concluded, the user may select the power company after the contract change as a specific power company on the power company selection screen of the terminal device. In this case, the terminal device transmits power related information corresponding to the power company after the contract change to the thermal equipment. And the control apparatus of a thermal equipment controls the operation | movement of a thermal equipment appropriately using the electric power related information corresponding to the electric power company after a contract change. Therefore, even if the electric power company with which the user signs a contract is changed, the control device can appropriately control the operation of the thermal equipment.

  When a specific power company is selected by the user, the terminal device allows the user to select a specific power plan for which the user has a contract from among a plurality of power plans provided by the specific power company. When a plan selection screen is displayed on the display unit and a specific power plan is selected by the user, specific power related information corresponding to a specific power plan provided by a specific power company may be transmitted to the thermal equipment. Good.

  In general, a power company provides a plurality of power plans. According to said structure, when a specific electric power company is selected by a user, a terminal device displays the plan selection screen for making a user select the specific electric power plan which has concluded the contract on a display part. For this reason, the user can select a specific power plan for which the user has a contract. Then, when a specific power plan is selected by the user, the terminal device transmits power-related information corresponding to the specific power company and the specific power plan to the thermal equipment. Therefore, the control device for the thermal equipment can appropriately control the operation of the thermal equipment by using the power related information corresponding to the specific power company and the specific power plan.

  The communication system may include a server. The terminal device may store a plurality of pieces of power related information including specific power related information corresponding to a specific power company. The server stores update information for updating the power-related information, and may receive the update information to the terminal device when receiving an update request for requesting transmission of the update information from the terminal device. When the terminal device transmits an update request to the server and receives update information from the server, the terminal device updates a plurality of power related information based on the update information, and transmits the updated specific power related information to the thermal equipment. May be.

  Specific power related information corresponding to a specific power company may be changed by a specific power company. In order to properly operate the thermal equipment, specific power-related information used by the thermal equipment, that is, specific power-related information stored in the memory of the terminal device needs to be updated to the latest state. . According to said structure, a terminal device receives the update information from a server by transmitting an update request to a server, and updates the specific electric power related information in memory. Then, the terminal device transmits the updated specific power related information to the thermal device. Therefore, the control device of the thermal equipment can appropriately control the operation of the thermal equipment using the updated specific power related information.

  The communication system may include a server. The server may store a plurality of pieces of power related information including specific power related information corresponding to a specific power company. When a specific electric power company is selected by the user, the terminal device transmits company information indicating that the specific electric power company has been selected to the server, and the specific electric power related to the specific electric power company is transmitted from the server. Information may be received and specific power related information received from the server may be transmitted to the thermal equipment. When the server receives company information from the terminal device, the server may transmit specific power related information corresponding to a specific power company from the plurality of power related information to the terminal device.

  According to said structure, the terminal device does not need to memorize | store several electric power relevant information. Therefore, the storage capacity of the terminal device can be reduced as compared with the case where a plurality of pieces of power-related information are stored in the terminal device.

It is a block diagram of the communication system of 1st Example. It is an example of the division | segmentation pattern memorize | stored in the remote control of 1st Example. It is an example of the electric power related information memorize | stored in the portable terminal of 1st Example. In 1st Example, it is a sequence diagram at the time of starting of a setting application. It is an example of the screen displayed on the display part of the portable terminal of 1st Example. In 1st Example, it is a sequence diagram at the time of the update of a setting application. In 1st Example, it is an operation | movement sequence diagram of a hot-water supply system. In 1st Example, it is a graph which shows an example of an electricity unit price and time. In 2nd Example, it is a sequence diagram at the time of starting of a setting application.

(First embodiment)
A communication system 2 according to this embodiment will be described with reference to FIGS. As shown in FIG. 1, the communication system 2 includes a hot water supply system 4, a mobile terminal 100, and an information management server 300.

(Configuration of hot water supply system 4)
The hot water supply system 4 includes a hot water supply device 10 and a remote controller 40. The hot water supply apparatus 10 includes a tank unit 12, an HP (heat pump) unit 14, a gas unit 16, and a hot water supply control unit 20.

  The tank unit 12 is a supply unit for storing hot water for hot water supply in a tank (not shown) and supplying the water stored in the tank to a hot water supply location (for example, a bathtub). A hot water supply path is connected to the tank, and hot water is supplied to the hot water supply location via the hot water supply path.

  The HP unit 14 is a heating unit for absorbing heat from outside air and heating water in the tank by driving a heat pump (not shown). The heat pump and the tank are connected via a heat storage circulation path. The heat storage circulation path circulates water in the tank between the heat pump and the tank. Thereby, the water in the tank is heated by the heat pump and returned to the tank of the tank unit 12.

  The gas unit 16 is a heating unit that heats the water flowing through the hot water supply path using a burner (not shown). The gas unit 16 is provided in the middle of the hot water supply path from the tank unit 12 to the hot water supply location.

  The hot water supply control unit 20 includes a CPU 22 and a memory 24. CPU22 controls operation of each component (tank unit 12, HP unit 14, gas unit 16) of hot-water supply device 10 according to a program memorized by memory 24, and makes hot-water supply operation mentioned later to hot-water supply device 10, A hot water filling operation or the like can be executed.

  The remote control 40 can communicate with the hot water supply apparatus 10. The remote controller 40 can be connected to the Internet 8 via the wireless LAN router 60 in a state where the wireless connection with the wireless LAN router 60 is established. The remote control 40 includes a display unit 42, an operation unit 44, and a remote control control unit 50. The display unit 42 is a display for displaying various information. The user can input various instructions to the remote control 40 by operating the operation unit 44. The various instructions are, for example, instructions for causing the hot water supply apparatus 10 to execute a hot water filling operation described later.

  The remote controller control unit 50 includes a CPU 52 and a memory 54. As shown in FIG. 2, the memory 54 stores a plurality of division patterns (P1, P2, P3...). In a plurality of division patterns, a seasonal division and a holiday are associated with each other. Each electric power company has different season categories and holidays. For this reason, the memory 54 stores a plurality of division patterns corresponding to electric power companies with which the user may conclude a contract. For example, the division pattern P1 corresponds to the seasonal division and holidays set by the A electric power company, and the division pattern P2 corresponds to the seasonal division and holidays set by the B electric power company.

  Next, a heating operation and a hot water filling operation executed by the CPU 22 of the hot water supply apparatus 10 will be described.

(Boiling operation)
The boiling operation is an operation for heating water in the tank. The CPU 22 drives the heat pump to heat the water in the tank to the boiling temperature (for example, 45 ° C.). When a predetermined amount of water in the tank is heated, the boiling operation ends. CPU22 performs a boiling operation, when the warm water in a tank becomes below a minimum amount of water (for example, 10L). Hereinafter, a state where the hot water in the tank is equal to or less than the lower limit water amount is referred to as a “hot water state”.

(Hot water operation)
The hot water filling operation is an operation for supplying hot water to a bathtub that is a hot water supply location. CPU22 heats the water in a tank by driving a heat pump, and supplies warm water to a bathtub. When the temperature of the water supplied from the tank to the bathtub is lower than the hot water supply set temperature (for example, 40 ° C.), the CPU 22 drives the burner to supply the water heated to the hot water supply set temperature to the hot water supply location. To do. When a predetermined amount of hot water is supplied to the bathtub, the hot water filling operation ends.

(Configuration of mobile terminal 100)
In FIG. 1, a mobile terminal 100 is a portable terminal device such as a mobile phone or a smartphone. The mobile terminal 100 can access the Internet 8. The mobile terminal 100 includes a display unit 102 and a terminal control unit 110. The display unit 102 is a display for displaying various information, and also functions as a so-called touch panel (that is, an operation unit). The terminal control unit 110 includes a CPU 112 and a memory 114. The CPU 112 controls the operation of the mobile terminal 100 according to a program stored in the memory 114. A setting application 116 is stored in the memory 114. The setting application 116 is installed in the mobile terminal 100 from a server (not shown) on the Internet 8, for example. The setting application 116 is an application provided by the manufacturer of the hot water supply system 4. The setting application 116 is an application for transmitting to the hot water supply system 4 power related information corresponding to the power company and power plan with which the user has a contract. When the setting application 116 is installed in the portable terminal 100, the memory 114 stores a plurality of power companies and a plurality of power plans provided by each power company. For example, the A power company provides a plan A1, a plan A2, a plan A3,. The memory 114 stores power related information corresponding to each of a plurality of power plans provided by each power company.

  FIG. 3 shows power related information corresponding to the plan A1 of the power company A. As shown in FIG. 3, in the power related information, different setting information 130 is stored for each season. Even in the same season, different setting information 130 is stored for each holiday and weekday. The setting information 130 includes the presence / absence of midnight time zone setting, end time of midnight time zone, presence / absence of peak time zone setting, start time of peak time zone, end time of peak time zone, unit price of electricity for peak time zone, boiling Presence / absence of driving function and classification pattern are included. The midnight time zone indicates a time zone of an electricity unit price (hereinafter referred to as “low electricity unit price PC”) lower than a normal electricity unit price (hereinafter referred to as “normal electricity unit price PN”). In the midnight time zone setting, “present” indicates that the midnight time zone is set, and “none” indicates that the midnight time zone is not set. The peak time zone indicates a time zone of an electricity unit price (hereinafter referred to as “high electricity unit price PH”) higher than the normal electricity unit price PN. In the peak time zone setting, “present” indicates that the peak time zone is set, and “none” indicates that the peak time zone is not set. The electricity unit price in the peak time zone is the high electricity unit price PH. The forward function of the boiling operation is a function that causes the water heater 10 to perform the boiling operation before the start time of the peak time period. The division pattern indicates a division pattern corresponding to each electric power company. Even if the power companies are the same, information other than the division pattern may be different if the power plans are different.

(Configuration of information management server 300)
In FIG. 1, the information management server 300 is a server provided by the manufacturer of the hot water supply system 4. The information management server 300 includes a server control unit 310. The server control unit 310 includes a CPU 312 and a memory 314. The memory 314 stores power related information 316. The administrator of the information management server 300 updates the power related information 316 when the power related information is changed by the power company. Accordingly, the latest state of the power related information 316 is maintained. For example, when the high electricity unit price PH of the plan A1 of the A power company is changed, the administrator of the information management server 300 sets the high electricity unit price PH of the plan A1 of the A power company in the power related information 316 to the latest high electricity. Update to unit price PH.

(Sequence at startup of setting application 116 (case A); FIG. 4)
Next, processing executed when the setting application 116 is activated will be described with reference to FIGS. 4 and 5. In this case, it is assumed that the user activates the setting application 116 for the first time. Moreover, the user has concluded the contract regarding the plan A1 of A electric power company. In the following, considering the ease of understanding, when describing the processing executed by the CPUs 22, 52, 112, 312 without describing the CPU as a main body, the apparatus (the hot water supply device 10, the remote controller 40, the portable device) is described. The terminal 100 and the information management server 300) are mainly described.

  In T10, an operation for starting the setting application 116 is executed by the user. In this case, the mobile terminal 100 activates the setting application 116 and displays the setting screen S1 on the display unit 102 at T12 (see FIG. 5A). The setting screen S1 is a screen for setting a power company with which the user has a contract and a power plan. The setting screen S1 is also a screen for setting a gas unit price.

  When the power company selection operation is executed by the user at T14, the portable terminal 100 displays the power company selection screen S2 on the display unit 102 at T16 (see FIG. 5B). The electric power company selection operation is an operation of touching a blank portion of the electric power company on the display unit 102. On the electric power company selection screen S2, electric power companies (A electric power company, B electric power company, C electric power company,...) That can be concluded by the user are displayed.

  When “A power company” is selected at T18 and the “complete” button is operated by the user, the portable terminal 100 displays a power plan setting selection screen S3 on the display unit 102 at T20 (FIG. 5C). )reference). On the power plan setting selection screen S3, a button (“Yes”) for selecting whether or not to set a power plan with which the user has a contract (hereinafter referred to as “contract power plan”), and “No”) is displayed. The user selects “Yes” when he / she remembers the contract power plan, and selects “No” when he / she does not remember the contract power plan. In this case, the user remembers that the contract power plan is “plan A1”.

  When the user operates a button (“Yes”) for setting a contract power plan at T22, the portable terminal 100 displays a power plan selection screen S4 on the display unit 102 at T24 (FIG. 5D). )reference). The power plan provided by the power company selected in T18 is displayed on the power plan selection screen S4. In this case, the power plan “plan A1, plan A2, plan A3, plan A4...” Provided by the power company A is displayed.

  When “plan A1” is selected in T26 and the “complete” button is operated by the user, the portable terminal 100 displays the setting screen S5 on the display unit 102 in T28 (see FIG. 5E). The setting screen S5 is different from the setting screen S1 of T12 in that “A power company (plan A1)” is displayed.

At T30, the gas unit price (450 yen / m ³ ) is input by the user (see FIG. 5F), and at T32, the “complete” button is operated by the user. In this case, the portable terminal 100 transmits a signal including “A power company” selected in T18 and “Plan A1” selected in T26 to the remote controller 40 in T40.

  When receiving a signal including the A power company and the plan A1 from the portable terminal 100 at T40, the remote controller 40 stores the A power company and the plan A1 in the memory 54 at T42.

  At T50, the portable terminal 100 transmits a signal including power related information (see FIG. 3) corresponding to the plan A1 of the power company A to the remote controller 40 from among the plurality of power related information stored in the memory 114. .

  When the remote controller 40 receives a signal including power-related information corresponding to the plan A1 of the power company A at T50 from the portable terminal 100, the remote controller 40 stores the power-related information in the memory 54 at T52. When receiving a signal including the gas unit price from the portable terminal 100 at T60, the remote controller 40 stores the gas unit price in the memory 54 at T62.

(Sequence when updating the setting application 116 (Case B); FIG. 6)
Next, with reference to FIG. 6, each process executed when the setting application 116 installed in the mobile terminal 100 is updated will be described. The initial state of FIG. 6 is a state after FIG. Therefore, the A power company and the plan A1 are stored in the memory 54 of the remote controller 40. This case assumes a situation in which the power related information of the plan A1 of the A power company is changed after FIG. In the following, communication between the mobile terminal 100 and the remote controller 40 is communication via the wireless LAN router 60. For this reason, in the following description, in the communication between the portable terminal 100 and the remote controller 40, the description “through the wireless LAN router 60” is omitted.

  When an operation for updating the setting application 116 is performed by the user at T110, the mobile terminal 100 executes an update process at T112. The mobile terminal 100 accesses a server (not shown) on the Internet 8 where the latest setting application 116 is registered, and downloads the latest setting application 116. Then, the mobile terminal 100 updates the setting application 116 in the memory 114 to the latest state.

  When the update process is completed, the portable terminal 100 transmits a first request signal to the remote controller 40 at T120. The first request signal is a signal for requesting the power related information 316 registered in the information management server 300. That is, it is a signal for requesting the latest power related information.

  When receiving the request signal at T120, the information management server 300 transmits the power related information 316 in the memory 314 to the portable terminal 100 at T122.

  When receiving the power related information 316 at T122, the portable terminal 100 updates the power related information in the memory 114 to the power related information 316 received at T122 at T130. Then, at T132, the mobile terminal 100 transmits a second request signal to the remote controller 40. The second request signal is a signal for requesting a power company and a power plan with which the user has a contract.

  When receiving the second request signal at T132, the remote controller 40 transmits a signal including the A power company and the plan A1 stored in the memory 54 to the portable terminal 100 at T134. In T140, the remote controller 40 receives the power related information corresponding to the A power company and the plan A1 from the portable terminal 100, and in T142, the power related information in the memory 54 is updated to the power related information received in T142. To do. Thereby, the power related information in the memory 54 is updated to the latest state.

(Operation sequence of hot water supply system 4 (Case C); FIG. 7)
Next, a process that is executed after the power-related information is stored in the remote controller 40 will be described. The date of this case is Monday, July 31, 2017. The remote controller 40 is configured to transmit the setting information 130 corresponding to the date of the current day to the hot water supply device 10 every 24 hours (for example, every time the time becomes 2:00).

  When 2:00 on Monday, July 31, 2017 arrives, the remote controller 40 determines that the day is a summer and a weekday, and in T210, setting information 130 (see FIG. 3) corresponding to the summer and the weekday. The thick line portion) is transmitted to the hot water supply apparatus 10.

  When the setting information 130 is received at T210, the water heater 10 identifies the first boiling start time T1 and the second boiling start time T2 at T212. The first boiling start time T1 is a time for storing hot water in the tank before the first hot water supply in the morning time zone (for example, 6:00 to 7:00) is performed. When the midnight time zone setting is “present”, the hot water supply device 10 specifies the first boiling start time T1 so that the boiling operation is completed before the end time of the midnight time zone. Specifically, the hot water supply apparatus 10 specifies a time that is a first predetermined time x1 before the end time of the midnight time zone (“5:00”) as the first boiling start time T1 (FIG. 8). reference). In addition, when the midnight time zone setting is “none”, the hot water supply device 10 specifies the first boiling start time T1 as “4:50”.

  The second boiling start time T2 is a time for storing hot water in the tank before the peak time zone. When the peak time zone is “none”, the hot water supply device 10 does not specify the second boiling start time T2. The hot water supply device 10 specifies the second boiling start time T2 so that the boiling operation is completed before the start time of the peak time period. Specifically, the hot water supply device 10 specifies a time that is a second predetermined time x2 before the start time (“13:00”) of the peak time period as the second boiling start time T2 (FIG. 8). reference).

  When the first boiling start time T1 arrives, the hot water supply apparatus 10 performs a boiling operation at T220. Thereby, the boiling operation is completed before the end time of the midnight time zone. Therefore, the boiling operation is executed during the midnight time zone in which the low electricity unit price PC is set. As a result, the unit price of electricity required for the boiling operation can be reduced.

  When the second boiling start time T2 arrives, the hot water supply apparatus 10 performs a boiling operation at T230. Thereby, the boiling operation is completed before the start time of the peak time zone. Therefore, it is possible to reduce the possibility that the tank will run out of hot water during the peak hours when the high electricity unit price PH is set. As a result, the unit price of electricity required for the boiling operation can be reduced. In the peak time zone, when the tank is out of hot water, the hot water supply device 10 uses the gas unit price and the high electricity unit price PH, and uses the heat pump to heat the water (hereinafter referred to as the utility cost). , Referred to as “first utility cost”) and the utility cost when water is heated using a burner (hereinafter referred to as “second utility cost”). The hot water supply device 10 performs the boiling operation when the first utility cost is lower than the second utility cost. On the other hand, when the first utility cost is higher than the second utility cost, the hot water supply device 10 does not execute the boiling operation. That is, the boiling operation is prohibited during the peak time period.

  As described above, the mobile terminal 100 displays the power company selection screen S2 on the display unit 102 (T16 in FIG. 4). Therefore, the user who uses the hot water supply system 4 can select “A power company”, which is a power company with which the user has a contract, from among a plurality of power companies. And when "A electric power company" is selected by the user (T18 of FIG. 4), the portable terminal 100 transmits the electric power related information (refer FIG. 3) corresponding to A electric power company to the hot water supply system 4 (in detail, Transmit to the remote control 40) (T50 in FIG. 4). Therefore, the hot water supply system 4 can control the operation of the hot water supply system 4 by using the power related information corresponding to the A power company with which the user has a contract.

  In addition, for example, when the user changes the power company with which the user concludes a contract from the A power company to the B power company, the user may select “B power company” on the power company selection screen S2. When “B power company” is selected by the user, portable terminal 100 transmits power related information corresponding to B power company to hot water supply system 4. The hot water supply system 4 controls the operation of the hot water supply system 4 using the power related information corresponding to the B power company. Therefore, even if the electric power company with which the user concludes the contract is changed, the hot water supply system 4 can appropriately control the operation of the hot water supply system 4.

  The portable terminal 100 displays the power plan selection screen S4 on the display unit 102 when “A power company” is selected by the user on the power company selection screen S2 (T18 in FIG. 4) (FIG. 4). T24). For this reason, the user can select “plan A1” for which the user has concluded a contract. Then, when “plan A1” is selected by the user (T26 in FIG. 4), the mobile terminal 100 transmits power related information corresponding to the power company A and the plan A1 to the thermal device. Therefore, the hot water supply system 4 can appropriately control the operation of the hot water supply system 4 using the power related information corresponding to the electric power company A and the plan A1.

  Further, the portable terminal 100 receives the latest power-related information 316 from the information management server 300 by transmitting a first request signal to the information management server 300 (T120 in FIG. 6) (T122 in FIG. 6). Then, the power related information in the memory 114 is updated (T130 in FIG. 6). And the portable terminal 100 transmits the electric power relevant information corresponding to the updated A electric power company to a thermal apparatus. Therefore, the hot water supply system 4 can appropriately control the operation of the hot water supply system 4 using the updated power-related information.

(Correspondence)
The hot water supply system 4, the portable terminal 100, and the information management server 300 are examples of “thermal equipment”, “terminal device”, and “server”, respectively. The hot water supply control unit 20 and the remote control unit 50 are examples of the “control device”. The A power company and the plan A1 are examples of “specific power company” and “specific power plan”, respectively. The memory 114 is an example of “memory”. The power related information 316 stored in the information management server 300 is an example of “update information”. The first request signal is an example of an “update request”.

(Second embodiment)
With reference to FIG. 9, the communication system 2 of 2nd Example is demonstrated. The memory 114 of the mobile terminal 100 according to the second embodiment is different from the mobile terminal 100 according to the first embodiment in that a plurality of pieces of power related information are not stored. That is, in the case of the second embodiment, when the setting application 116 is installed in the mobile terminal 100, the memory 114 stores only a plurality of power companies and a plurality of power plans provided by each power company.

(Sequence at startup of setting application 116 (case D); FIG. 9)
With reference to FIG. 9, each process performed when the setting application 116 is started will be described. The initial state of FIG. 9 is the same as the initial state of FIG.

  First, the same processing as T10 to T32 in FIG. 4 is executed. Then, the mobile terminal 100 transmits a third request signal including the A power company and the plan A1 to the information management server 300 at T340. The third request signal is a signal requesting to transmit power related information corresponding to the power company and the power plan included in the signal.

  When receiving the third request signal at T340, the information management server 300 carries the power-related information corresponding to the A power company and the plan A1 from the power-related information 316 stored in the memory 314 at T342. It transmits to the terminal 100. T350 to T372 are the same as T40 to T62 in FIG. Also in this embodiment, the same effects as in the first embodiment can be exhibited.

  Further, the memory 114 of the mobile terminal 100 does not store a plurality of pieces of power related information. Therefore, the storage capacity of the memory 114 can be reduced as compared with the case where a plurality of pieces of power-related information are stored in the memory 114.

(Correspondence)
The third request signal is an example of “company information”.

  Specific examples of the present invention have been described in detail above, but 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.

  In the first example, when the setting application 116 is updated, the power related information stored in the memory 114 of the mobile terminal 100 is updated. In the state after FIG. 4, the power related information stored in the memory 114 of the mobile terminal 100 may be updated when the setting application 116 is activated.

  The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology exemplified in this specification or the drawings can achieve a plurality of objects at the same time, and has technical usefulness by achieving one of the objects.

2: Communication system 4: Hot-water supply system 8: Internet 10: Hot-water supply device 12: Tank unit 14: HP unit 16: Gas unit 20: Hot-water supply control unit 22: CPU
24: Memory 40: Remote control 42: Display unit 44: Operation unit 50: Remote control unit 52: CPU
54: Memory 60: Wireless LAN router 100: Mobile terminal 102: Display unit 110: Terminal control unit 112: CPU
114: Memory 116: Setting application 130: Setting information 300: Information management server 310: Server control unit 312: CPU
314: Memory 316: Power related information

Claims (4)

A communication system comprising a thermal device and a terminal device,
The thermal equipment is
A control device for controlling the operation of the thermal device;
The terminal device
An electric power company selection screen for selecting a specific electric power company with which the user using the thermal equipment has a contract from among a plurality of electric power companies is displayed on the display unit,
When the specific power company is selected by the user, specific power related information corresponding to the specific power company is transmitted to the thermal equipment,
The control device of the thermal equipment is
Receiving the specific power related information from the terminal device;
The communication system which controls operation | movement of the said thermal apparatus using the said specific electric power related information. The terminal device
When the specific power company is selected by the user, the specific power plan for which the user has a contract is selected from among a plurality of power plans provided by the specific power company. Display the plan selection screen on the display,
The specific power related information corresponding to the specific power plan provided by the specific power company is transmitted to the thermal device when the specific power plan is selected by the user. Communication system. The communication system includes a server,
The terminal device
Storing a plurality of power related information including the specific power related information corresponding to the specific power company;
The server
Storing update information for updating the power-related information;
When receiving an update request for requesting transmission of the update information from the terminal device, the update information is transmitted to the terminal device,
The terminal device
Sending the update request to the server;
When receiving the update information from the server, based on the update information, update the plurality of power related information,
The communication system according to claim 1 or 2, wherein the updated specific power-related information is transmitted to the thermal device. The communication system includes a server,
The server
Storing a plurality of power related information including the specific power related information corresponding to the specific power company;
The terminal device
When the specific power company is selected by the user, the company information indicating that the specific power company has been selected is transmitted to the server,
Receiving the specific power related information corresponding to the specific power company from the server;
Transmitting the specific power related information received from the server to the thermal device;
The server
When receiving the company information from the terminal device, the specific power related information corresponding to the specific power company from the plurality of power related information is transmitted to the terminal device.
The communication system according to claim 1 or 2.

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