JP7507411B2 - PROGRAM, TERMINAL DEVICE, AND REFRIGERATOR CONTROL SYSTEM - Google Patents

Description

The present invention relates to a program and a terminal device.

Conventionally, there is known a technology for causing a refrigerator to execute an operation involving a change in the temperature inside the refrigerator using a terminal device. For example, Patent Document 1 discloses a technology in which a user terminal, which is a terminal device carried by a user, instructs the refrigerator to execute a power-saving operation, and the refrigerator, upon receiving the instruction, executes a power-saving operation and raises the set temperature inside the refrigerator.

JP 2014-088987 A

Refrigerators such as those described in Patent Document 1 come in two types: one in which the controlled object receives an instruction indicating the internal temperature when performing an operation that changes the internal temperature, and another in which the controlled object receives an instruction indicating the operation and performs the operation. Therefore, if the terminal device is configured to be able to send an instruction corresponding to only one of the types, it cannot send an instruction corresponding to the other type to the refrigerator, and therefore cannot cause the other type of refrigerator to perform an operation that changes the internal temperature.

In view of the above, the present invention aims to make it possible to cause a refrigerator to perform an operation involving changing the internal temperature via a terminal device, regardless of the type of refrigerator.

In order to achieve the above object, the present invention provides a program that causes a control unit of a terminal device capable of communicating with a refrigerator to function as a first processing unit that, when causing the refrigerator to execute a predetermined operation involving a change in the internal temperature, transmits, to a first type of refrigerator, a first instruction to instruct the refrigerator to change the internal temperature, a second processing unit that, when causing the refrigerator to execute the predetermined operation, transmits, to a second type of refrigerator, a second instruction to instruct the refrigerator to execute the predetermined operation, and a detection unit that detects whether or not a user is located in a store where food can be purchased, wherein when the detection unit detects that the user is located in the store and the type of the refrigerator with which the terminal device communicates is the first type, the first processing unit transmits the first instruction, and when the detection unit detects that the user is located in the store and the type of the refrigerator with which the terminal device communicates is the second type, the second processing unit transmits the second instruction.

According to the present invention, a terminal device can cause a refrigerator to perform an operation that changes the internal temperature, regardless of the type of refrigerator.

Diagram showing the configuration of a refrigerator control system A block diagram showing the functional configuration of a refrigerator, a terminal device, and a refrigerator control system. A flowchart showing the operation of a refrigerator control system equipped with a first type refrigerator. FIG. 1 is a diagram for specifically explaining the operation of a refrigerator control system including a first type refrigerator. A flowchart showing the operation of a refrigerator control system equipped with a second type refrigerator. FIG. 11 is a diagram for specifically explaining the operation of a refrigerator control system including a second type refrigerator.

A first invention is a program that causes a control unit of a terminal device capable of communicating with a refrigerator to function as a first processing unit that, when causing the refrigerator to execute a predetermined operation involving a change in the internal temperature, transmits, to a first type refrigerator, a first instruction to instruct the refrigerator to change the internal temperature, and a second processing unit that, when causing the refrigerator to execute the predetermined operation, transmits, to a second type refrigerator, a second instruction to instruct the refrigerator to execute the predetermined operation.
According to this, when causing the refrigerator to execute a predetermined operation that changes the internal temperature, the terminal device can transmit to the refrigerator an instruction for controlling a different target depending on the type of refrigerator. Therefore, the terminal device can cause the refrigerator to execute an operation that changes the internal temperature regardless of the type of refrigerator.

A second invention is characterized in that the second type refrigerator is a refrigerator that, after performing the specified operation, ends the specified operation when a specified time has elapsed and returns the internal temperature to the temperature before performing the specified operation, and the first processing unit, after transmitting the first instruction, transmits a third instruction to instruct the user to return the internal temperature to the temperature before transmitting the first instruction, and the second processing unit, after transmitting the second instruction, does not transmit an instruction to end the specified operation.
According to this, after the refrigerator changes the internal temperature by executing a specified operation, a process can be performed to return the internal temperature to the state before the change depending on the type of refrigerator. Therefore, the terminal device can cause the refrigerator to end the execution of an operation involving a change in the internal temperature regardless of the type of refrigerator.

A third invention is characterized in that the specified operation is an operation of lowering the temperature inside the cabinet from a temperature before the specified operation is performed, and the first instruction is an instruction to lower the temperature inside the cabinet from a temperature before the first instruction is sent.
This allows the internal temperature of the refrigerator to be lowered using the terminal device regardless of the type of refrigerator.

A fourth invention is characterized in that the specified operation is an operation of raising the temperature inside the cabinet from a temperature before the specified operation is performed, and the first instruction is an instruction to raise the temperature inside the cabinet from a temperature before the first instruction is sent.
This allows the internal temperature of the refrigerator to be increased using the terminal device regardless of the type of refrigerator.

A fifth invention is characterized in that the first type of refrigerator is an older model than the second type of refrigerator, and the second type of refrigerator is a newer model than the first type of refrigerator.
This allows the terminal device to cause the refrigerator to execute an operation involving a change in the internal temperature, regardless of whether the refrigerator is new or old.

A sixth invention is characterized in that the program is an application program that can be installed in the terminal device.
According to this, a terminal device that does not have a function for changing the internal temperature of a refrigerator can be made to have the function by installing an application program, and therefore a general-purpose terminal device can be made to be a terminal device that can cause a refrigerator to execute an operation involving changing the internal temperature regardless of the type of refrigerator.

A seventh invention is a terminal device capable of communicating with a refrigerator, comprising a control unit that transmits, to a first type refrigerator, a first instruction to instruct the refrigerator to change an internal temperature, and transmits, to a second type refrigerator, a second instruction to instruct the refrigerator to execute a specific operation to change the internal temperature.
According to this, when causing the refrigerator to execute a predetermined operation that changes the internal temperature, the terminal device can transmit to the refrigerator an instruction for controlling a different target depending on the type of refrigerator. Therefore, the terminal device can cause the refrigerator to execute an operation that changes the internal temperature regardless of the type of refrigerator.

Figure 1 shows the configuration of the refrigerator control system 1000.

The refrigerator control system 1000 is a system in which a terminal device 2 used by a user P of the refrigerator 1 controls the refrigerator 1 via a global network GN. The global network GN includes the Internet, a telephone network, and other communication networks.

The refrigerator control system 1000 includes a refrigerator 1. In FIG. 1, the refrigerator 1 is installed in the home H of a user P. The refrigerator 1 includes a main box 10 with an open front, in which a refrigerator compartment 11, an ice-making compartment 12, a fresh-freezing compartment 13, a freezer compartment 14, and a vegetable compartment 15 are formed. A rotating left door 11A and a right door 11B are provided at the opening at the front of the refrigerator compartment 11. The ice-making compartment 12, the fresh-freezing compartment 13, the freezer compartment 14, and the vegetable compartment 15 are each provided with drawers 12A, 13A, 14A, and 15A for storing food.

In this embodiment, the refrigerator 1 is connected to a communication device 4 installed in the home H of the user P, and communicates with the refrigerator control server 3 via the communication device 4.

The communication device 4 connects to the global network GN and communicates with the refrigerator control server 3 connected to the global network GN. The communication device 4 functions as an interface device for connecting the refrigerator 1 to the global network GN. When the terminal device 2 has established a communication connection with the communication device 4, the communication device 4 functions as an interface device for connecting the terminal device 2 to the global network GN. The communication device 4 has functions such as a modem function, a router function, and a NAT (Network Address Translation) function. The communication device 4 transfers data exchanged between the refrigerator 1 and the refrigerator control server 3 connected to the global network GN. The communication device 4 transfers data exchanged between the terminal device 2 that has established a communication connection and the refrigerator control server 3 connected to the global network GN.

The refrigerator control system 1000 includes a terminal device 2 having a touch panel 22. The terminal device 2 is, for example, a smartphone or a tablet terminal. An application program for controlling the refrigerator 1 is installed in the terminal device 2. In the following description, the application program for controlling the refrigerator 1 is referred to as a "refrigerator control app" and is given the reference number "213". The refrigerator control app 213 corresponds to the "program" and "application program" of the present invention.

In FIG. 1, a user P who is at home is indicated by a dotted line, and a user P who has left home H is indicated by a solid line. When the terminal device 2 is used by a user P who is at home, the terminal device 2 controls the refrigerator 1 by communicating with the refrigerator control server 3 connected to the global network GN via the communication device 4 or without the communication device 4 using the function of the refrigerator control app 213. When the terminal device 2 is used by a user P who has left home H, the terminal device 2 controls the refrigerator 1 by communicating with the refrigerator control server 3 connected to the global network GN without the communication device 4 using the function of the refrigerator control app 213.

The terminal device 2, using the functions of the installed refrigerator control app 213, sends instructions to the refrigerator 1 for different control targets depending on the type of refrigerator 1 with which it communicates, causing the refrigerator 1 to perform pre-cooling operation that involves changing the internal temperature. Pre-cooling operation corresponds to the "predetermined operation" of the present invention. Pre-cooling operation is an operation that lowers the internal temperature of the refrigerator 1 below that during normal operation, power saving operation, etc.

Here, we will explain the types of refrigerator 1. In this embodiment, there are a first type and a second type of refrigerator 1. The first type of refrigerator 1 is an older model of refrigerator 1 than the second type of refrigerator 1, and the second type of refrigerator 1 is a newer model of refrigerator 1 than the first type of refrigerator 1.

The first type refrigerator 1 is a refrigerator 1 capable of changing the inside temperature to a temperature corresponding to any one of the stages of "weak", "medium", and "strong". The inside temperature of the first type refrigerator 1 decreases in the order of "weak", "medium", and "strong". When the first type refrigerator 1 receives an inside temperature change instruction HS from the terminal device 2, it changes the inside temperature based on the received inside temperature change instruction HS. The inside temperature change instruction HS is information instructing a change in the inside temperature of the first type refrigerator 1, the control object indicates the inside temperature, and the control content indicates a change in the inside temperature. For example, an inside temperature change instruction HS instructing a change in the inside temperature to a temperature corresponding to the "strong" stage indicates that the control object indicates the inside temperature, and the control content indicates a change in the inside temperature to a temperature corresponding to the "strong" stage. The inside temperature change instruction HS is information of a command system corresponding to the first type refrigerator 1, and is not recognized by the second type refrigerator 1. When the first type refrigerator 1 receives from the terminal device 2 an internal temperature change instruction HS instructing the user to change the internal temperature from the current temperature to a lower temperature, the refrigerator 1 lowers the internal temperature and executes pre-cooling operation. When the first type refrigerator 1 receives from the terminal device 2 an internal temperature change instruction HS instructing the user to return the internal temperature to the temperature before the change, the refrigerator 1 returns the internal temperature to the temperature before the pre-cooling operation was executed and ends the pre-cooling operation.

The second type refrigerator 1 is a refrigerator 1 that performs pre-cooling operation and is capable of changing the internal temperature to a temperature corresponding to the pre-cooling operation. The second type refrigerator 1 performs pre-cooling operation when it receives a pre-cooling operation execution instruction US from the terminal device 2. The pre-cooling operation execution instruction US corresponds to the "second instruction" of the present invention. The pre-cooling operation execution instruction US is information instructing the execution of pre-cooling operation, the control object indicates pre-cooling operation, and the control content indicates the execution of pre-cooling operation. The pre-cooling operation execution instruction US is information in a command system corresponding to the second type refrigerator 1, and is not recognized by the first type refrigerator 1.
The second type refrigerator 1 automatically ends the pre-cooling operation when a predetermined time (e.g., two hours) has elapsed after the pre-cooling operation is performed. Therefore, the terminal device 2 transmits a pre-cooling operation execution instruction US to the second type refrigerator 1, but does not transmit an instruction to end the pre-cooling operation.

Returning to the explanation of FIG. 1, the refrigerator control system 1000 includes a refrigerator control server 3. The refrigerator control server 3 is a server device that controls the refrigerator 1 and is connected to the global network GN. Note that in each figure, the refrigerator control server 3 is represented by a single block, but this does not necessarily mean that the refrigerator control server 3 is composed of a single server device. For example, the refrigerator control server 3 may be composed of multiple server devices with different processing contents.

Next, the functional configurations of the refrigerator 1, the terminal device 2, and the refrigerator control server 3 will be described.
FIG. 2 is a block diagram showing the functional configuration of the refrigerator 1, the terminal device 2, and the refrigerator control server 3.

First, the functional configuration of the refrigerator 1 will be described.
The refrigerator 1 includes a refrigerator control unit 16, a refrigerator communication unit 17, and a cooling unit 18.

The refrigerator control unit 16 includes a refrigerator processor 160, which is a processor that executes programs such as a CPU or MPU, and a refrigerator memory unit 161, and controls each part of the refrigerator 1. The refrigerator control unit 16 executes various processes through cooperation between hardware and software, such that the refrigerator processor 160 reads out a control program 1611 stored in the refrigerator memory unit 161 and executes the processes.

The refrigerator memory unit 161 has a memory area for storing programs executed by the refrigerator processor 160 and data processed by the refrigerator processor 160. The refrigerator memory unit 161 stores a control program 1611 executed by the refrigerator processor 160, refrigerator setting data 1612 which is setting data related to the settings of the refrigerator 1, a refrigerator ID 1613 which is identification information of the refrigerator 1, and various other data. An example of the refrigerator ID 1613 is the serial number of the refrigerator 1. The refrigerator memory unit 161 has a non-volatile memory area for non-volatilely storing programs and data. The refrigerator memory unit 161 may also have a volatile memory area and constitute a work area for temporarily storing programs executed by the refrigerator processor 160 and data to be processed.

The refrigerator communication unit 17 includes communication hardware that complies with a specific communication standard, and communicates with devices connected to the global network GN according to the specific communication standard under the control of the refrigerator control unit 16. In this embodiment, the refrigerator communication unit 17 communicates with the refrigerator control server 3 according to the specific communication standard. The communication standard used by the refrigerator communication unit 17 may be a wireless communication standard or a wired communication standard.

The cooling unit 18 includes mechanisms for cooling each storage compartment of the refrigerator 1, such as a compressor 181, a condenser 182, a capillary tube 183, a cooler 184, a cooling fan 185 that sends the cold air generated by the cooler 184 to each storage compartment, and a damper 186 that divides the cold air sent by the cooling fan 185, and cools each storage compartment of the refrigerator 1 according to the control of the refrigerator control unit 16.

When the refrigerator control unit 16 of the first type refrigerator 1 receives an internal temperature change instruction HS from the terminal device 2 via the refrigerator communication unit 17, the refrigerator control unit 16 controls the rotation speed of the compressor 181, the rotation speed of the cooling fan 185, etc. so that the internal temperature becomes a temperature corresponding to the stage indicated by the internal temperature change instruction HS.
For example, when the internal temperature of the refrigerator 1 is a temperature corresponding to the "medium" stage, the refrigerator control unit 16 of the first type refrigerator 1 receives an internal temperature change instruction HS to change the internal temperature to a temperature corresponding to the "strong" stage. In this case, the refrigerator control unit 16 of the first type refrigerator 1 increases the rotation speed of the compressor 181 to increase the amount of cooling in the refrigerator 1, increases the rotation speed of the cooling fan 185 to increase the amount of cold air circulating in the refrigerator 1 to increase the amount of cooling in the refrigerator 1, and increases the rotation speed of the compressor 181 and the rotation speed of the cooling fan 185 to increase the amount of cooling in the refrigerator 1. As a result, the internal temperature of the first type refrigerator 1 is changed from a temperature corresponding to the "medium" stage to a temperature corresponding to the "strong" stage.

When the refrigerator control unit 16 of the second type refrigerator 2 receives a pre-cooling operation execution instruction US from the terminal device 2 via the refrigerator communication unit 17, the refrigerator control unit 16 executes the pre-cooling operation. In the pre-cooling operation, for example, the refrigerator control unit 16 increases the rotation speed of the compressor 181 from the rotation speed during normal operation, power saving operation, etc., to increase the amount of cooling inside the refrigerator 1. In addition, for example, in the pre-cooling operation, the refrigerator control unit 16 increases the rotation speed of the cooling fan 185 from the rotation speed during normal operation, power saving operation, etc., to increase the amount of cold air circulating in the refrigerator 1, and to increase the amount of cooling inside the refrigerator 1. In addition, for example, in the pre-cooling operation, the refrigerator control unit 16 increases the rotation speed of the compressor 181 and the rotation speed of the cooling fan 185 from the rotation speed during normal operation, power saving operation, etc., to increase the amount of cooling inside the refrigerator 1. As a result, in the pre-cooling operation, the temperature inside the refrigerator 1 drops from the temperature during normal operation, power saving operation, etc.

Next, the functions of the refrigerator control server 3 will be described.
The refrigerator control server 3 includes a server control unit 30 and a server communication unit 31.

The server control unit 30 includes a server processor 300, which is a processor that executes programs such as a CPU or MPU, and a server memory unit 310, and controls each part of the refrigerator control server 3. The server control unit 30 executes various processes through cooperation between hardware and software, such that the server processor 300 reads the control program 311 stored in the server memory unit 310 and executes the processes.

The server memory unit 310 has a memory area for storing programs executed by the server processor 300 and data processed by the server processor 300. The server memory unit 310 stores a control program 311 executed by the server processor 300, server setting data 312 which is setting data related to the settings of the refrigerator control server 3, a refrigerator control database 313, and various other data. The server memory unit 310 has a non-volatile memory area for non-volatilely storing programs and data. The server memory unit 310 may also have a volatile memory area and constitute a work area for temporarily storing programs executed by the server processor 300 and data to be processed.

The refrigerator control database 313 is a database that stores various information related to the operation control of the refrigerator 1. Each record R stored in the refrigerator control database 313 has a user ID 3131, a refrigerator ID 1613, and communication information 3132. Each record R stored in the refrigerator control database 313 may further have one or more other types of information.

The user ID 3131 is identification information that identifies the user P who uses the refrigerator control app 213, and is appropriately assigned to the user P who uses the refrigerator control app 213.

As described above, refrigerator ID 1613 is identification information for refrigerator 1.

The communication information 3132 is information for communicating with refrigerator 1 having refrigerator ID 1613 associated with the same record R. The communication information 3132 includes, for example, address information and security information.

The server communication unit 31 has communication hardware that complies with a specific communication standard, and communicates with devices connected to the global network GN according to the specific communication standard under the control of the server control unit 30. In this embodiment, the server communication unit 31 communicates with the refrigerator 1 and the terminal device 2.

Next, the functional configuration of the terminal device 2 will be described.
The terminal device 2 includes a terminal control unit 20, a terminal communication unit 21, a touch panel 22, and a GPS receiving unit 23. The terminal control unit 20 corresponds to the "control unit" of the present invention.

The terminal control unit 20 includes a terminal processor 200, which is a processor that executes programs such as a CPU or MPU, and a terminal storage unit 210, and controls each unit of the terminal device 2. The terminal control unit 20 executes various processes through cooperation between hardware and software, such that the terminal processor 200 reads out a control program 211 stored in the terminal storage unit 210 and executes the process. A refrigerator control app 213 is pre-installed in the terminal device 2. The refrigerator control app 213 is a program that is read out from the terminal storage unit 210 by the terminal processor 200 and executed, causing the terminal control unit 20 to function as a setting unit 201, a detection unit 202, and an operation control unit 203. Details of these functional units will be described later.

The terminal storage unit 210 has a storage area for storing programs executed by the terminal processor 200 and data processed by the terminal processor 200. The terminal storage unit 210 stores a control program 211 executed by the terminal processor 200, terminal setting data 212 which is setting data relating to the settings of the terminal device 2, a refrigerator control app 213, app setting data 214 relating to the settings of the refrigerator control app 213, and various other data. The terminal storage unit 210 has a non-volatile storage area for non-volatilely storing programs and data. The terminal storage unit 210 may also have a volatile storage area and constitute a work area for temporarily storing programs executed by the terminal processor 200 and data to be processed.

The application setting data 214 is data that describes the combination of the setting items of the refrigerator control application 213 and the setting values corresponding to the setting items. The setting items of the refrigerator control application 213 include at least setting items related to a user ID 3131 and the type of refrigerator 1. The user ID 3131 assigned to user P is set as the setting value in the setting item related to the user ID 3131. Type information 2141 indicating the type of refrigerator is set as the setting value in the setting item related to the type of refrigerator 1.

In the application setting data 214, the setting item related to the type of refrigerator 1 is set to either type information 2141 indicating the first type or type information 2141 indicating the second type.

The terminal communication unit 21 has communication hardware that complies with a specific communication standard, and communicates with devices connected to the global network GN according to the specific communication standard under the control of the terminal control unit 20. The terminal communication unit 21 communicates with the refrigerator control server 3 according to the specific communication standard through the function of the refrigerator control app 213. The communication standard used by the terminal communication unit 21 is a wireless communication standard.

The touch panel 22 includes a display panel such as a liquid crystal display panel, and a touch sensor that is overlaid on or integrated with the display panel. The display panel displays various images under the control of the terminal control unit 20. The touch sensor detects touch operations and outputs the detected operations to the terminal control unit 20. The terminal control unit 20 executes processing corresponding to the touch operations based on the input from the touch sensor.

The GPS receiver 23 periodically receives GPS signals from GPS satellites using an antenna (not shown), and includes hardware that calculates the position (e.g., latitude and longitude) of the terminal device 2 based on the received GPS signals. The GPS receiver 23 generates position data indicating the calculated position of the terminal device 2, and outputs the data to the terminal control unit 20.

As described above, the terminal control unit 20 functions as a setting unit 201, a detection unit 202, and an operation control unit 203.

The setting unit 201 performs various settings related to the functions of the refrigerator control app 213. The setting unit 201 performs various settings of the refrigerator control app 213 by setting values to the setting items contained in the app setting data 214.

For example, when setting the user ID 3131 as a setting value for a setting item related to the user ID 3131, the setting unit 201 receives the user ID 3131 from the refrigerator control server 3 and sets the received user ID 3131 to the setting item for the user ID 3131.

For example, when setting type information 2141 as a setting value for a setting item related to the type of refrigerator 1, setting unit 201 causes touch panel 22 to display a user interface for selecting whether the type of refrigerator 1 is the first type or the second type. When user P performs an operation to select either the first type or the second type in the displayed user interface, setting unit 201 sets type information 2141 indicating the selected type as a setting value for the setting item related to the type of refrigerator 1.

The detection unit 202 detects whether or not the user P is located in a store TP where food can be purchased. The detection unit 202 outputs the detection result to the operation control unit 203. For example, the detection unit 202 acquires the position of the terminal device 2 by the GPS receiving unit 23 at a predetermined cycle, and determines whether or not the distance between the acquired position of the terminal device 2 and a store TP that has been previously determined as a detection target is equal to or less than a predetermined distance. If the detection unit 202 determines that the distance between the position of the terminal device 2 and the store TP exceeds the predetermined distance, it detects that the user P is not located in the store TP. On the other hand, if the detection unit 202 determines that the distance between the current position of the terminal device 2 and the store TP is equal to or greater than the predetermined distance, it detects that the user P is located in the store TP.

The operation control unit 203 functions as a first processing unit 2031 when type information 2141 indicating a first type is set in the setting item related to the type of refrigerator 1 in the application setting data 214. On the other hand, the operation control unit 203 functions as a second processing unit 2032 when type information 2141 indicating a second type is set in the setting item related to the type of refrigerator 1 in the application setting data 214.

When the detection unit 202 detects that the user P is located in the store TP, the first processing unit 2031 sends an instruction to change the internal temperature HS twice to the refrigerator 1.

The first processing unit 2031 transmits an inside temperature change instruction HS to the refrigerator 1 to instruct the refrigerator 1 to change the inside temperature from the current temperature to a lower temperature. In the following description, the inside temperature change instruction HS to instruct the refrigerator 1 to change the inside temperature from the current temperature to a lower temperature is referred to as an "inside temperature decrease instruction" and is denoted by the symbol "HS1." The inside temperature decrease instruction HS1 corresponds to the "first instruction" of the present invention.
For example, if the current internal temperature is a temperature corresponding to the "medium" stage, the first processing unit 2031 sends to the refrigerator 1 an internal temperature decrease instruction HS1 to change the internal temperature to a temperature corresponding to the "strong" stage.
Also, for example, when the current inside temperature is a temperature corresponding to the "low" stage, the first processing unit 2031 transmits an inside temperature decrease instruction HS1 to the refrigerator 1 to change the inside temperature to a temperature corresponding to the "medium" or "high" stage. Note that when the current inside temperature is a temperature corresponding to the "high" stage, the first processing unit 2031 may or may not transmit the inside temperature decrease instruction HS1 to the refrigerator 1.

When a predetermined time (e.g., two hours) has elapsed since transmitting the inside temperature decrease instruction HS1, the first processing unit 2031 transmits to the refrigerator 1 an inside temperature change instruction HS instructing the refrigerator 1 to return the inside temperature to the temperature before the inside temperature decrease instruction HS1 was transmitted. In the following description, the inside temperature change instruction HS instructing the refrigerator 1 to return the inside temperature to the temperature before the inside temperature decrease instruction HS1 was transmitted is referred to as an "inside temperature return instruction" and is denoted by the symbol "HS2." The inside temperature return instruction HS2 corresponds to the "third instruction" of the present invention.
For example, if the internal temperature of refrigerator 1 is changed from a temperature corresponding to the "medium" stage to a temperature corresponding to the "strong" stage by transmitting an internal temperature decrease instruction HS1, the first processing unit 2031 transmits an internal temperature return instruction HS2 to refrigerator 1 instructing it to return the internal temperature to a temperature corresponding to the "medium" stage.

When the detection unit 202 detects that the user P is located in the store TP, the second processing unit 2032 transmits a pre-cooling operation execution instruction US to the refrigerator 1. As described above, the second type refrigerator 1 automatically ends pre-cooling operation when a predetermined time (e.g., two hours) has elapsed after performing pre-cooling operation. Therefore, the terminal device 2 transmits a pre-cooling operation execution instruction US to the second type refrigerator 1, but does not transmit an instruction to end pre-cooling operation.

Next, the operation of the refrigerator control system 1000 will be described with reference to FIGS.
Fig. 3 is a flowchart showing the operation of refrigerator control system 1000 including the first type refrigerator 1. In Fig. 3, flowchart FA shows the operation of terminal device 2, flowchart FB shows the operation of refrigerator control server 3, and flowchart FC shows the operation of the first type refrigerator 1.

The flowchart shown in FIG. 3 is based on the premise that type information 2141 indicating the first type is set in the setting item related to the type of refrigerator 1 in the application setting data 214, and the operation control unit 203 functions as the first processing unit 2031. In addition, it is based on the premise that at the start of the flowchart shown in FIG. 3, the internal temperature of refrigerator 1 is a temperature corresponding to the "medium" stage.

Based on the detection result from the detection unit 202, the driving control unit 203 determines whether the detection unit 202 has detected that the user P is located at the store TP (step SA1).

If the operation control unit 203 determines that the detection unit 202 has not detected that the user P is located in the store TP (step SA1: NO), it performs the determination in step SA1 again.

On the other hand, if the operation control unit 203 determines that the detection unit 202 has detected that the user P is located in the store TP (step SA1: YES), the operation control unit 203 determines whether the type of refrigerator 1 with which the terminal device 2 is communicating is the first type or the second type (step SA2).

If type information 2141 indicating a first type is set in the setting item related to the type of refrigerator 1 in the application setting data 214, the operation control unit 203 determines in step SA2 that the type of refrigerator 1 is the first type. On the other hand, if type information 2141 indicating a second type is set in the setting item related to the type of refrigerator 1 in the application setting data 214, the operation control unit 203 determines in step SA2 that the type of refrigerator 1 is the second type.

When the operation control unit 203 determines that the type of refrigerator 1 with which the terminal device 2 is communicating is the second type (step SA2: "second type"), it functions as the second processing unit 2032 and transitions the process to step SD3 in FIG. 5.

On the other hand, if the operation control unit 203 determines that the type of refrigerator 1 with which the terminal device 2 is communicating is the first type (step SA2: "first type"), it functions as the first processing unit 2031. Then, the first processing unit 2031 sends an instruction to decrease the internal temperature HS1 to the refrigerator control server 3 via the terminal communication unit 21 (step SA3). In step SA3, the first processing unit 2031 sends the instruction to decrease the internal temperature HS1, to which the user ID 3131 stored in the terminal memory unit 210 has been added, to the refrigerator control server 3.

Referring to the flowchart FB, the server control unit 30 of the refrigerator control server 3 determines whether the server communication unit 31 has received an instruction to decrease the internal temperature HS1 from the terminal device 2 (step SB1).

If the server control unit 30 determines that an internal temperature decrease instruction HS1 has been received (step SB1: YES), it refers to the refrigerator control database 313 to identify the record R that includes the user ID 3131 that was added to the internal temperature decrease instruction HS1 (step SB2).

Based on the communication information 3132 included in the identified record R, the server control unit 30 transmits the internal temperature decrease instruction HS1 received from the terminal device 2 to the refrigerator 1 via the server communication unit 31 (step SB3). In step SB3, the server control unit 30 adds the refrigerator ID 1613 included in the record R identified in step SB2 and transmits the internal temperature decrease instruction HS1.

Referring to the flow chart FC, the refrigerator control unit 16 of the refrigerator 1 determines whether the refrigerator communication unit 17 has received an instruction to lower the internal temperature HS1 from the refrigerator control server 3 (step SC1).

When the refrigerator control unit 16 determines that an internal temperature decrease instruction HS1 has been received (step SC1: YES), it determines whether the refrigerator ID 1613 added to the received internal temperature decrease instruction HS1 matches the refrigerator ID 1613 stored in the refrigerator memory unit 161 (step SC2).

If the refrigerator control unit 16 determines that the refrigerator ID 1613 matches (step SC2: YES), it changes the internal temperature of the refrigerator 1 to a temperature corresponding to the "high" setting (step SC3).

On the other hand, if the refrigerator control unit 16 determines that the refrigerator ID 1613 does not match (step SC2: NO), the refrigerator control unit 16 ends this process. In other words, the refrigerator control unit 16 does not change the internal temperature of the refrigerator 1 from the temperature corresponding to the "medium" stage.

Returning to the explanation of the flowchart FA, when the first processing unit 2031 transmits the instruction to decrease the internal temperature HS1 via the terminal communication unit 21, it determines whether or not a predetermined time has elapsed since the instruction to decrease the internal temperature HS1 was transmitted (step SA4).

If the first processing unit 2031 determines that the predetermined time has not elapsed since the instruction to decrease the temperature inside the storage unit HS1 was sent (step SA4: NO), it performs the determination in step SA4 again.

On the other hand, if the first processing unit 2031 determines that a predetermined time has elapsed since sending the inside temperature decrease instruction HS1 (step SA4: YES), it sends an inside temperature return instruction HS2 to the refrigerator control server 3 via the device communication unit 21 (step SA5). In step SA5, the first processing unit 2031 sends the inside temperature return instruction HS2, to which the user ID 3131 stored in the device storage unit 210 has been added, to the refrigerator control server 3.

Referring to the flowchart FB, the server control unit 30 of the refrigerator control server 3 determines whether the server communication unit 31 has received an internal temperature return instruction HS2 from the terminal device 2 (step SB4).

If the server control unit 30 determines that the internal temperature return instruction HS2 has been received (step SB4: YES), it refers to the refrigerator control database 313 to identify the record R that includes the user ID 3131 that was added to the internal temperature return instruction HS2 (step SB5).

Based on the communication information 3132 included in the identified record R, the server control unit 30 transmits the internal temperature return instruction HS2 received from the terminal device 2 to the refrigerator 1 via the server communication unit 31 (step SB6). In step SB6, the server control unit 30 adds the refrigerator ID 1613 included in the record R identified in step SB5 and transmits the internal temperature return instruction HS2.

Referring to the flowchart FC, the refrigerator control unit 16 of the refrigerator 1 determines whether the refrigerator communication unit 17 has received the internal temperature return instruction HS2 from the refrigerator control server 3 (step SC4).

When the refrigerator control unit 16 determines that the internal temperature return instruction HS2 has been received (step SC4: YES), it determines whether the refrigerator ID 1613 added to the received internal temperature return instruction HS2 matches the refrigerator ID 1613 stored in the refrigerator memory unit 161 (step SC5).

If the refrigerator control unit 16 determines that the refrigerator ID 1613 matches (step SC5: YES), it changes the internal temperature of the refrigerator 1 to a temperature corresponding to the "medium" stage (step SC6).

On the other hand, if the refrigerator control unit 16 determines that the refrigerator ID 1613 does not match (step SC6: NO), it terminates this process.

Figure 4 is a diagram for specifically explaining the operation of the refrigerator control system 1000 including the first type refrigerator 1. The explanation of Figure 4 illustrates an example in which the internal temperature of the first type refrigerator 1 is changed to temperatures corresponding to each stage in the order of "Medium" → "High" → "Medium".

In FIG. 4, situation ST1 shows a case where the detection unit 202 detects that the user P is located in the store TP, and the terminal device 2 transmits an instruction to decrease the internal temperature HS1 to the refrigerator 1 via the global network GN using the function of the refrigerator control app 213. When the refrigerator 1 receives the instruction to decrease the internal temperature HS1, it performs pre-cooling operation by changing the internal temperature to a temperature corresponding to the "high" stage.

In FIG. 4, status ST2 shows a case where user P returns home to home H within a predetermined time after refrigerator 1 changes the internal temperature to a temperature corresponding to the "strong" stage, i.e., after performing pre-cooling operation. As shown in status ST1 and status ST2, the first type refrigerator 1 can lower the internal temperature before user P stores food in refrigerator 1. Thus, the first type refrigerator 1 can prevent a temporary rise in the internal temperature caused by user P storing food in refrigerator 1, and can also quickly bring the temperature of newly stored food to an optimal storage temperature. Thus, refrigerator control system 1000 equipped with first type refrigerator 1 can prevent the freshness of already stored food and newly stored food from decreasing.

In FIG. 4, situation ST3 shows a case where a predetermined time has passed since refrigerator 1 changed the internal temperature to a temperature corresponding to the "high" stage after user P has returned home from home H, and terminal device 2 has sent internal temperature return instruction HS2 to refrigerator 1 via global network GN. Upon receiving internal temperature return instruction HS2, refrigerator 1 ends pre-cooling operation by returning the internal temperature to a temperature corresponding to the "medium" stage. In situation ST3 in FIG. 4, user P has returned home to home H, so there is a high possibility that refrigerator 1 contains food purchased by user P at store TP, and there is no need to continue to set the internal temperature to a temperature corresponding to the "high" stage. Therefore, refrigerator 1 can return the internal temperature to a temperature corresponding to the "medium" stage at an appropriate time.

Figure 5 is a flowchart showing the operation of the refrigerator control system 1000 equipped with the second type refrigerator 1. In Figure 5, the flowchart FD shows the operation of the terminal device 2, the flowchart FE shows the operation of the refrigerator control server 3, and the flowchart FF shows the operation of the second type refrigerator 1.

The flowchart shown in FIG. 5 is based on the premise that type information 2141 indicating the second type is set in the setting item related to the type of refrigerator 1 in the application setting data 214, and the operation control unit 203 functions as the second processing unit 2032. In addition, it is based on the premise that at the start of the flowchart shown in FIG. 5, the second type refrigerator 1 is performing an operation other than pre-cooling operation, such as normal operation or power saving operation.

Based on the detection result from the detection unit 202, the driving control unit 203 determines whether the detection unit 202 has detected that the user P is located at the store TP (step SD1).

If the operation control unit 203 determines that the detection unit 202 has not detected that the user P is located in the store TP (step SD1: NO), it performs the determination in step SD1 again.

On the other hand, if the operation control unit 203 determines that the detection unit 202 has detected that the user P is located in the store TP (step SD1: YES), the operation control unit 203 determines whether the type of refrigerator 1 with which the terminal device 2 is communicating is the first type or the second type (step SD2).

If type information 2141 indicating a first type is set in the setting item related to the type of refrigerator 1 in the application setting data 214, the operation control unit 203 determines in step SD2 that the type of refrigerator 1 is the first type. On the other hand, if type information 2141 indicating a second type is set in the setting item related to the type of refrigerator 1 in the application setting data 214, the operation control unit 203 determines in step SD2 that the type of refrigerator 1 is the second type.

When the operation control unit 203 determines that the type of the refrigerator 1 with which the terminal device 2 is communicating is the first type (step SD2: "first type"), it functions as the first processing unit 2031 and transitions the process to step SA3 in FIG. 3.

On the other hand, if the operation control unit 203 determines that the type of refrigerator 1 with which the terminal device 2 is communicating is the second type (step SD2: "second type"), it functions as the second processing unit 2032. Then, the second processing unit 2032 sends a pre-cooling operation execution instruction US to the refrigerator control server 3 via the terminal communication unit 21 (step SD3). In step SD3, the second processing unit 2032 sends the pre-cooling operation execution instruction US, to which the user ID 3131 stored in the terminal storage unit 210 has been added, to the refrigerator control server 3.

Referring to the flowchart FE, the server control unit 30 of the refrigerator control server 3 determines whether or not a pre-cooling operation execution instruction US has been received from the terminal device 2 via the server communication unit 31 (step SE1).

If the server control unit 30 determines that a pre-cooling operation execution instruction US has been received (step SE1: YES), it refers to the refrigerator control database 313 to identify the record R that includes the user ID 3131 that was added to the pre-cooling operation execution instruction US (step SE2).

Based on the communication information 3132 included in the identified record R, the server control unit 30 transmits the pre-cooling operation execution instruction US received from the terminal device 2 to the refrigerator 1 via the server communication unit 31 (step SE3). In step SE3, the server control unit 30 transmits the pre-cooling operation execution instruction US, adding the refrigerator ID 1613 included in the record R identified in step SE2.

Referring to flowchart FF, the refrigerator control unit 16 of the refrigerator 1 determines whether or not a pre-cooling operation execution instruction US has been received from the refrigerator control server 3 via the refrigerator communication unit 17 (step SF1).

When the refrigerator control unit 16 determines that a pre-cooling operation execution instruction US has been received (step SF1: YES), it determines whether the refrigerator ID 1613 added to the received pre-cooling operation execution instruction US matches the refrigerator ID 1613 stored in the refrigerator memory unit 161 (step SF2).

If the refrigerator control unit 16 determines that the refrigerator ID 1613 matches (step SF2: YES), it starts pre-cooling operation (step SF3).

The refrigerator control unit 16 determines whether a predetermined time has elapsed since the start of pre-cooling operation (step SF4).

If the refrigerator control unit 16 determines that the predetermined time has not elapsed since the start of pre-cooling operation (step SF4: NO), it performs the determination in step SF4 again.

On the other hand, if the refrigerator control unit 16 determines that a predetermined time has elapsed since the start of pre-cooling operation (step SF4: YES), it ends the pre-cooling operation (step SF5).

Figure 6 is a diagram for specifically explaining the operation of the refrigerator control system 1000 equipped with the second type refrigerator 1. Also, at the start of the flowchart shown in Figure 6, it is assumed that the second type refrigerator 1 is performing an operation other than pre-cooling operation, such as normal operation or power saving operation.

In FIG. 6, situation ST4 shows a case where the detection unit 202 detects that the user P is located in the store TP, and the terminal device 2 transmits a pre-cooling operation execution instruction US to the refrigerator 1 via the global network GN. When the refrigerator 1 receives the pre-cooling operation execution instruction US, it starts the pre-cooling operation.

In FIG. 6, situation ST5 shows a case where user P returns home to home H within a predetermined time after refrigerator 1 starts pre-cooling operation. As shown in situations ST4 and ST5, the second type refrigerator 1 can lower the temperature inside the refrigerator 1 by pre-cooling operation before user P stores food in the refrigerator 1. This provides the same effect as the refrigerator control system 1000 equipped with the first type refrigerator 1 described with reference to FIG. 4.

In FIG. 6, when a predetermined time has elapsed since refrigerator 1 started pre-cooling operation in situation ST5, refrigerator 1 ends pre-cooling operation. As in situation ST5, pre-cooling operation can be ended at the timing when user P returns to home H within the predetermined time after starting pre-cooling operation, so refrigerator 1 can end pre-cooling operation at an appropriate timing.

As described above, the refrigerator control app 213 causes the terminal control unit 20 of the terminal device 2 capable of communicating with the refrigerator 1 to function as a first processing unit 2031 that transmits an internal temperature decrease instruction HS1 to the first type refrigerator 1 to instruct the refrigerator 1 to change the internal temperature when the refrigerator 1 is caused to perform a pre-cooling operation that involves a change in the internal temperature, and a second processing unit 2032 that transmits a pre-cooling operation execution instruction US to the second type refrigerator 1 to instruct the refrigerator 1 to perform a pre-cooling operation that changes the internal temperature when the refrigerator 1 is caused to perform a pre-cooling operation.

The terminal device 2 capable of communicating with the refrigerator 1 includes a terminal control unit 20 that transmits an internal temperature decrease instruction HS1 to the first type refrigerator 1 to change the internal temperature when performing pre-cooling operation, and transmits a pre-cooling operation execution instruction US to the second type refrigerator 1 to execute pre-cooling operation that changes the internal temperature when performing pre-cooling operation.

The refrigerator control app 213 and the terminal device 2 allow the terminal device 2 to send to the refrigerator 1 instructions for controlling different objects depending on the type of the refrigerator 1 when performing pre-cooling operation. Therefore, the refrigerator control app 213 and the terminal device 2 allow the terminal device 2 to cause the refrigerator 1 to perform pre-cooling operation involving a change in the internal temperature, regardless of the type of the refrigerator 1.

The second type of refrigerator 1 is a refrigerator 1 that terminates the pre-cooling operation after a predetermined time has elapsed after performing the pre-cooling operation, and returns the inside temperature to the temperature before the pre-cooling operation was performed. After transmitting the inside temperature decrease instruction HS1, the first processing unit 2031 transmits an inside temperature return instruction HS2 that instructs the inside temperature to be returned to the temperature before the inside temperature decrease instruction HS1 was transmitted. After transmitting the pre-cooling operation execution instruction US, the second processing unit 2032 does not transmit an instruction to end the pre-cooling operation.

According to this, after the refrigerator 1 changes the internal temperature by executing the pre-cooling operation, a process can be executed to return the internal temperature to the state before the change depending on the type of refrigerator 1. Therefore, the terminal device 2 can cause the refrigerator 1 to end the execution of the pre-cooling operation regardless of the type of refrigerator 1.

Pre-cooling operation is an operation to lower the temperature inside refrigerator 1. The instruction to lower the temperature inside HS1 is an instruction to lower the temperature inside.

This allows the internal temperature of the refrigerator 1 to be lowered using the terminal device 2, regardless of the type of refrigerator 1.

The first type of refrigerator 1 is an older model than the second type of refrigerator 1. The second type of refrigerator 1 is a newer model than the first type of refrigerator 1.

This allows the terminal device 2 to cause the refrigerator 1 to perform pre-cooling operation regardless of whether the model of the refrigerator 1 is new or old.

The refrigerator control app 213 is an application program that can be installed on the terminal device 2.

Accordingly, a terminal device 2 that does not have a function for changing the temperature inside the refrigerator 1 can be made into a terminal device 2 that has that function by installing the refrigerator control app 213. Therefore, a general-purpose terminal device 2 can be made into a terminal device 2 that can cause the refrigerator 1 to perform pre-cooling operation regardless of the type of refrigerator 1.

The above-described embodiment merely shows one aspect of the present invention, and any modification and application is possible within the scope of the present invention.

For example, in the embodiment described above, when the detection unit 202 detects that the user P is located in the store TP, the detection unit 202 automatically transmits an instruction to lower the internal temperature HS1 to the first type refrigerator 1 and an instruction to perform pre-cooling operation US to the second type refrigerator 2. However, the terminal device 2 may be configured to inquire of the user P whether or not to lower the internal temperature of the refrigerator 1 when the detection unit 202 detects that the user P is located in the store TP. In this configuration, when the terminal device 2 receives an instruction from the user P to lower the internal temperature of the refrigerator 1 after the inquiry, the terminal device 2 transmits an instruction to lower the internal temperature HS1 to the first type refrigerator 1 and transmits an instruction to perform pre-cooling operation US to the second type refrigerator 2.

In addition, for example, in the above-mentioned embodiment, the pre-cooling operation is exemplified as the predetermined operation of the present invention, but the predetermined operation of the present invention is not limited to the pre-cooling operation, and may be other operations such as power-saving operation in which power consumption is smaller than other operations. In the power-saving operation, the temperature inside the refrigerator rises, for example, from that during normal operation. In addition, when the predetermined operation of the present invention is the power-saving operation, the terminal device 2 transmits an internal temperature change instruction HS to the refrigerator 1, which instructs the refrigerator 1 to change the internal temperature from the current temperature to a higher temperature, by using the function of the refrigerator control app 213. For example, when the current internal temperature is a temperature corresponding to the "medium" stage, the first processing unit 2031 transmits an internal temperature change instruction HS to the refrigerator 1, which changes the internal temperature to a temperature corresponding to the "low" stage. Then, when a predetermined time has elapsed after transmitting the internal temperature change instruction HS, the first processing unit 2031 transmits an internal temperature change instruction HS to the refrigerator 1, which changes the internal temperature to a temperature corresponding to the "medium" stage. In this example, the internal temperature change instruction HS transmitted first from the terminal device 2 corresponds to the "first instruction" of the present invention, and the internal temperature change instruction HS transmitted later from the terminal device 2 corresponds to the "third instruction" of the present invention.

In addition, for example, in the above-described embodiment, the refrigerator control server 3 adds the refrigerator ID 1613 when sending the internal temperature decrease instruction HS1, the internal temperature return instruction HS2, and the pre-cooling operation execution instruction US to the refrigerator 1. However, the refrigerator control server 3 may be configured to send these instructions to the refrigerator 1 without adding the refrigerator ID 1613. In this configuration, the refrigerator 1 performs pre-cooling operation without executing the processes of steps SC2 and SC5 in FIG. 3 and step SF2 in FIG. 5. In this configuration, the refrigerator storage unit 161 does not need to store the refrigerator ID 1613. In this configuration, one record R stored in the refrigerator control database 313 does not need to have the refrigerator ID 1613.

In addition, for example, in the above-described embodiment, when the detection unit 202 detects that the user P is located in the store TP, the refrigerator 1 is configured to transmit an instruction to change the internal temperature HS or an instruction to perform pre-cooling operation US, but the trigger for transmitting the instruction to change the internal temperature HS or the instruction to perform pre-cooling operation US is not limited to detection by the detection unit 202. The trigger for transmitting the instruction to change the internal temperature HS or the instruction to perform pre-cooling operation US may be, for example, the user P launching the refrigerator control app 213 and performing an operation in the refrigerator control app 213 that indicates the transmission of the instruction to change the internal temperature HS or the instruction to perform pre-cooling operation US.

For example, in the above embodiment, the terminal device 2 and the refrigerator 1 communicate with each other via the refrigerator control server 3 connected to the global network GN. However, the terminal device 2 and the refrigerator 1 may communicate with each other directly, without communicating with each other via the global network GN. In this configuration, the refrigerator ID 1613 of the refrigerator 1 with which the terminal device 2 and the refrigerator 1 communicate directly is described as a setting value in the application setting data 214, and the terminal device 1 adds this refrigerator ID 1613 when sending various instructions.

For example, in the above-described embodiment, the first type refrigerator 1 is an older model than the second type refrigerator 1, and the second type refrigerator 1 is a newer model than the first type refrigerator 1. However, the first type refrigerator 1 and the second type refrigerator 1 are not limited to refrigerators 1 of different models, and may be refrigerators 1 manufactured in different places, for example.

In addition, for example, the detection unit 202 may detect whether or not the user P is located at the store TP by cooperating with an application program having a current location display function, a navigation function, etc., such as a map application.

For example, the types of compartments formed in the main box 10 of the refrigerator are not limited to the refrigerator compartment 11, ice-making compartment 12, fresh-freezing compartment 13, freezer compartment 14, and vegetable compartment 15, and there may be fewer or more types of compartments. Also, the number of doors provided at the opening on the front of the refrigerator compartment 11 may be one.

Furthermore, the functions of the refrigerator control unit 16, the terminal control unit 20, and the server control unit 30 may be realized by multiple processors or semiconductor chips.

The components shown in FIG. 2 are merely examples, and the specific implementation form is not particularly limited. In other words, it is not necessary to implement hardware that corresponds to each component individually, and it is of course possible to implement a configuration in which one processor executes a program to realize the functions of each component. Also, in the above-described embodiment, some of the functions realized by software may be hardware, or some of the functions realized by hardware may be software. In addition, the specific detailed configurations of the other components of the refrigerator 1, the terminal device 2, and the refrigerator control server 3 may also be changed as desired without departing from the spirit of the present invention.

For example, the step units of the operation shown in FIG. 3 and FIG. 5 are divided according to the main processing contents in order to facilitate understanding of the operation of each part of the refrigerator control system 1000, and the present invention is not limited by the manner in which the processing units are divided or the names thereof. The processing units may be further divided into more step units according to the processing contents. Also, one step unit may be further divided to include more processing. Also, the order of the steps may be changed as appropriate within the scope of the present invention.

As described above, the program and terminal device according to the present invention can be used to change the temperature inside a refrigerator using the terminal device.

1 Refrigerator 2 Terminal device 20 Terminal control unit (control unit)
213 Refrigerator control application (program, application program)
2031 First processing unit 2032 Second processing unit HS1 Inner temperature lowering instruction (first instruction)
HS2 Internal temperature return indication (third indication)
US Pre-cooling operation execution command (second command)

Claims (9)

A control unit of a terminal device capable of communicating with the refrigerator,
a first processing unit that transmits, to the refrigerator of a first type, a first instruction to change the internal temperature when causing the refrigerator to execute a predetermined operation involving a change in the internal temperature;
a second processing unit that transmits a second instruction to instruct a second type refrigerator to execute the predetermined operation when the refrigerator is caused to execute the predetermined operation;
a detection unit that detects whether or not the user is located in a store where food can be purchased ;
When the detection unit detects that the user is located in the store and the type of the refrigerator with which the terminal device communicates is the first type, the first processing unit transmits the first instruction,
When the detection unit detects that the user is located in the store and the type of the refrigerator with which the terminal device communicates is the second type, the second processing unit transmits the second instruction.
A program characterized by: The second type refrigerator is a refrigerator that, after performing the predetermined operation, ends the predetermined operation when a predetermined time has elapsed, and returns an internal temperature to a temperature before the execution of the predetermined operation,
The first processing unit transmits a third instruction to instruct the user to return the internal temperature to a temperature before the first instruction is transmitted, after the first instruction is transmitted;
The second processing unit does not transmit an instruction to end the predetermined operation after transmitting the second instruction.
2. The program according to claim 1 . The predetermined operation is an operation of lowering the inside temperature from a temperature before the execution of the predetermined operation,
The first instruction is an instruction to lower the inside temperature from the temperature before the transmission of the first instruction.
3. The program according to claim 1 or 2. The predetermined operation is an operation of raising the temperature inside the storage compartment from a temperature before the predetermined operation is performed,
The first instruction is an instruction to increase the inside temperature from the temperature before the transmission of the first instruction.
3. The program according to claim 1 or 2. The first type of refrigerator is an older model than the second type of refrigerator,
The second type of refrigerator is a newer model than the first type of refrigerator.
5. The program according to claim 1, wherein the program is a program for executing a program. The program is an application program that can be installed in the terminal device.
6. The program according to claim 1, wherein the program is a program for executing a program. A terminal device capable of communicating with a refrigerator,
a control unit that transmits a first instruction to the first type refrigerator to instruct the refrigerator to change the internal temperature when causing the refrigerator to execute a predetermined operation involving a change in internal temperature, and transmits a second instruction to the second type refrigerator to instruct the refrigerator to execute the predetermined operation to change the internal temperature when causing the refrigerator to execute the predetermined operation , and detects whether or not a user is located in a store where food can be purchased ,
The control unit is
transmitting the first instruction when it is detected that the user is located in the store and the type of the refrigerator with which the terminal device communicates is the first type;
transmitting the second instruction when it is detected that the user is located in the store and the type of the refrigerator with which the terminal device communicates is the second type;
A terminal device comprising: A refrigerator control system including a refrigerator and a terminal device capable of communicating with the refrigerator,
The terminal device
a first processing unit that transmits, to the refrigerator of a first type, a first instruction to change the internal temperature when causing the refrigerator to execute a predetermined operation involving a change in the internal temperature;
a second processing unit that transmits a second instruction to instruct a second type refrigerator to execute the predetermined operation when the refrigerator is caused to execute the predetermined operation;
A detection unit that detects whether or not a user is located in a store where food can be purchased,
When the detection unit detects that the user is located in the store and the type of the refrigerator with which the terminal device communicates is the first type, the first processing unit transmits the first instruction,
When the detection unit detects that the user is located in the store and the type of the refrigerator with which the terminal device communicates is the second type, the second processing unit transmits the second instruction.
A refrigerator control system comprising: The first type refrigerator and the second type refrigerator store a refrigerator ID,
The first type refrigerator receives the first instruction, and when a refrigerator ID added to the received first instruction matches a stored refrigerator ID, changes an internal temperature;
the second type refrigerator receives the second instruction, and changes an internal temperature when a refrigerator ID added to the received second instruction matches a stored refrigerator ID;
9. The refrigerator control system according to claim 8.

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