JP2023008072A - Cold insulation time predicting system - Google Patents

Abstract

To provide a cold insulation time predicting system preliminarily predicting a cold insulation time at the time of power failure before the power is failed.SOLUTION: A cold insulation time predicting system includes: a refrigerator 10 provided with a cooler 20 cooling the inside refrigerator; and a server control part 41 acquiring a predicting cold insulation time at the time of power failure on the basis of a set temperature inside the refrigerator 10 or an actually measured temperature inside the refrigerator when occurence of power failure is preliminarily predicted. Accordingly, the predicted cold insulation time at the time of power failure is acquired by the server control part 41 and the power failure is notified to a user, so that a cold insulation status inside the refrigerator 10 is grasped when the power failure occurs and thereby food management inside the refrigerator can be performed at the time of power failure.SELECTED DRAWING: Figure 4

Description

The present disclosure relates to a cooling time prediction system.

In Patent Document 1, when a power failure of the commercial power supply occurs and the power is restored, the temperature of the storage room is detected by the temperature detection unit, and if the temperature of the storage room is higher than the predetermined notification temperature, the power failure is notified. A technique for notifying by department is disclosed.

JP 2013-160422 A

The present disclosure provides a cold storage time prediction system capable of predicting in advance the cold storage time in the event of a power failure before the power failure.

The cold storage time prediction system according to the present disclosure includes a refrigerator equipped with a cooler that cools the inside of the refrigerator, and when a power failure is predicted in advance, based on the set temperature inside the refrigerator or the actually measured temperature inside the refrigerator, the power failure and a control unit that obtains an estimated cold storage time in the case where the cold storage is performed and notifies the user of the predicted cold storage time.

In the cold storage time prediction system according to the present disclosure, the control unit obtains the predicted cold storage time in the event of a power failure, and notifies the user of this. , food can be managed in the refrigerator during a power outage.

Longitudinal sectional view of the refrigerator in Embodiment 1 Block diagram showing cold storage time prediction system Graph showing an example of predicted cold storage time in a refrigerator A graph showing an example of generating a predicted cold storage time based on the measured internal temperature in a refrigerator Explanatory diagram showing a display example of the touch panel of the terminal device according to Embodiment 1 Timing chart showing an example of a case where the cooling time is predicted by the database based on the information obtained in advance in the first embodiment Timing chart showing another example in the case of estimating the cooling time by the database based on the information obtained in advance in the first embodiment Timing chart showing an example of predicting cold storage time using the database in Embodiment 1 4 is a timing chart showing an example of a case where the refrigerator predicts the cooling time according to the first embodiment. 4 is a timing chart showing an example of a case where the terminal device predicts the cooling time according to Embodiment 1. Timing chart showing an example of estimating the cooling time based on the measured values in the first embodiment Timing chart showing an example of predicting cold storage time using the database in Embodiment 2 Timing chart showing an example of estimating the cooling time based on the measured values in the second embodiment Timing chart showing an example of estimating the cooling time based on the measured values in the second embodiment Timing chart showing an example of the case where the refrigerator predicts the cooling time based on the measured values in the second embodiment Timing chart showing an example of a case where the terminal device predicts the cooling time based on the measured values in the second embodiment

(Knowledge, etc. on which this disclosure is based)
At the time when the inventors came up with the present disclosure, when a commercial power failure occurred and the power was restored, the temperature of the storage chamber was detected by the temperature detection unit, and the temperature of the storage chamber was higher than the predetermined notification temperature. There was a technology to notify by a power failure alarm unit when it is on.

In the conventional technology, when the power supply is restored from a power failure, a notification is given when the temperature inside the refrigerator is high. It becomes possible to manage food and the like. However, the inventors discovered the problem that it is difficult to predict the cooling time in the refrigerator, and have come to constitute the main subject of the present disclosure in order to solve the problem.
Therefore, the present disclosure provides a cold storage time prediction system capable of predicting in advance the cold storage time in the event of a power failure before the power failure.

Hereinafter, embodiments will be described in detail with reference to the drawings. However, more detailed description than necessary may be omitted. For example, detailed descriptions of well-known matters or redundant descriptions of substantially the same configurations may be omitted.
It should be noted that the accompanying drawings and the following description are provided to allow those skilled in the art to fully understand the present disclosure and are not intended to limit the claimed subject matter thereby.

(Embodiment 1)
Embodiment 1 will be described below with reference to the drawings.
[1-1. Constitution]
FIG. 1 is a longitudinal sectional view of refrigerator 10 according to Embodiment 1. FIG.

As shown in FIG. 1, a refrigerator 10 has a box-shaped housing 11 with an open front. A refrigerator compartment 12 is formed above the housing 11 , and a freezer compartment 13 is formed below the housing 11 . A partition wall 14 is provided between the refrigerator compartment 12 and the freezer compartment 13 .
The refrigerator 10 is provided with a side-opening door 15 that can be freely opened and closed at the front opening of the refrigerating chamber 12 . The freezer compartment 13 is provided with a drawer 16 for storing food.

A duct 17 communicating vertically is provided behind the refrigerator compartment 12 and the freezer compartment 13 of the refrigerator 10 .
A plurality of refrigerating outlets 18 communicating with the duct 17 are formed behind the refrigerating compartment 12 .
A plurality of freezing discharge ports 19 communicating with the duct 17 are formed behind the freezer compartment 13 .
A cooler 20 functioning as an evaporator is arranged at a position corresponding to the rear of the freezer compartment 13 in the duct 17 . A cooling fan 21 is arranged above the cooler 20 in the duct 17 . A damper 22 is provided at a position corresponding to the partition wall 14 of the duct 17 to adjust the amount of cool air cooled by the cooler 20 driven by the cooling fan 21 and sent to the refrigerator compartment 12 .

A compressor 23 is arranged in the rear upper portion of the refrigerator compartment 12 . The compressor 23, the condenser (not shown), the expansion mechanism, and the cooler 20 are connected by refrigerant pipes to form a refrigeration cycle.
By discharging the refrigerant from the compressor 23, the refrigerant is cooled to a predetermined temperature, and heat is exchanged with the air flowing through the duct 17 to generate cool air.
Cooling fan 21 circulates the cold air in refrigerator compartment 12 or freezer compartment 13 to cool the inside of refrigerator compartment 12 or freezer compartment 13 .

[1-1-2. Configuration of cold storage time prediction system]
Next, the cooling time prediction system 1 using the refrigerator 10 described above will be described.
FIG. 2 is a block diagram showing the cooling time prediction system 1. As shown in FIG.
As shown in FIG. 2, the cooling time prediction system 1 is a system in which devices connected to the global network GN control the refrigerator 10 via the global network GN. The global network GN includes the Internet, telephone networks and other communication networks.
The cold storage time prediction system 1 includes a refrigerator 10 , a refrigerator management server 40 and a terminal device 50 .

First, the control configuration of refrigerator 10 will be described.
Refrigerator 10 includes refrigerator control unit 30 , refrigerator communication unit 31 , cooling unit 32 , and sensor unit 33 .
The refrigerator control unit 30 is composed of a processor such as a CPU or an MPU that executes programs, and includes a refrigerator storage unit 34 . Refrigerator control unit 30 reads a control program stored in refrigerator storage unit 34 and controls refrigerator 10 through cooperation of hardware and software.

Refrigerator storage unit 34 has a storage area for storing programs executed by refrigerator control unit 30 and data processed by refrigerator control unit 30 .
The refrigerator storage unit 34 stores a control program executed by the refrigerator control unit 30, setting data related to settings of the refrigerator 10, and various other data. The refrigerator storage unit 34 has a nonvolatile storage area. Refrigerator storage unit 34 may also include a volatile storage area and configure a work area for refrigerator control unit 30 .

The refrigerator communication unit 31 includes communication hardware conforming to a predetermined communication standard, and communicates with devices connected to the global network GN according to the predetermined communication standard under the control of the refrigerator control unit 30 . Refrigerator communication unit 31 communicates with refrigerator management server 40 according to a predetermined communication standard. The communication standard used by the refrigerator communication unit 31 may be a wireless communication standard (for example, IEEE802.11a/11b/11g/11n/11ac, Bluetooth (registered trademark)) or a wired communication standard.

Cooling unit 32 cools the storage chambers of refrigerator 10 by means of compressor 23 , cooling fan 21 , damper 22 , and other mechanisms for cooling storage chambers of refrigerator 10 under the control of refrigerator control unit 30 .

The sensor unit 33 includes various sensors such as a temperature sensor for detecting the temperature inside the refrigerator 10 and an open/close sensor for detecting opening/closing of the door 15 and the drawer 16 provided in the refrigerator 10. is output to the refrigerator control unit 30 .
As shown in FIG. 1, the sensor unit 33 includes a refrigerator compartment temperature sensor 35 and a freezer compartment temperature sensor 36 as temperature sensors.
Refrigerating compartment temperature sensor 35 is provided at a predetermined position in refrigerating compartment 12 to detect the internal temperature of refrigerating compartment 12 .
The freezer compartment temperature sensor 36 is provided at a predetermined position in the freezer compartment 13 and detects the internal temperature of the freezer compartment 13 .
Ambient temperature sensor 37 is provided at a predetermined position outside refrigerator 10 to detect the ambient temperature of refrigerator 10 .

Refrigerator control unit 30 is controlled in either a normal operation mode or a pre-cooling operation mode in which the internal temperature of refrigerator 10 is lower than in the normal operation mode.
Refrigerator 10 can perform cooling operation in stages of "weak", "medium", and "strong" in normal operation mode for refrigerator compartment 12 and/or freezer compartment 13, respectively.
For example, when the refrigerator compartment 12 is in the normal operation mode, the temperature is set to 5°C for "weak", 4°C for "medium", and 3°C for "strong". When the refrigerator compartment 12 is in the precooling operation mode, the temperature is set to 3°C.
For example, when the freezer compartment 13 is in the normal operation mode, the temperature is set to -18°C for "weak", -20°C for "medium", and -22°C for "strong". In the case of the precooling operation mode of the freezer compartment 13, it is set to -28°C.

Next, the configuration of refrigerator management server 40 will be described.
Refrigerator management server 40 includes server control unit 41 and server communication unit 42 .

The server control unit 41 includes a processor such as a CPU and an MPU that executes programs, and includes a server storage unit 43 . Server control unit 41 reads a control program stored in server storage unit 43 and controls each unit of refrigerator management server 40 through cooperation of hardware and software.

The server storage unit 43 has a storage area for storing programs executed by the server control unit 41 and data processed by the server control unit 41 . The server storage unit 43 stores a control program executed by the server control unit 41, setting data related to setting of the refrigerator management server 40, the cold storage management database 44, and various other data. The server storage unit 43 has a nonvolatile storage area. Moreover, the server storage unit 43 may include a volatile storage area and configure a work area for the server control unit 41 .

The cold storage management database 44 is a database that stores various information related to operation control of the refrigerator 10 . The cold storage management database 44 stores the refrigerator ID, the predicted cold storage time information of the refrigerator 10, and the like.

The server communication unit 42 includes communication hardware conforming to a predetermined communication standard, and under the control of the server control unit 41, communicates with devices connected to the global network GN according to the predetermined communication standard. In the present embodiment, server communication unit 42 communicates with refrigerator 10, terminal device 50, and a power failure prediction server.

The cold storage management database 44 stores the predicted cold storage time information of the refrigerator 10 as described above.
For each refrigerator 10, the predicted cold storage time information includes the internal temperature of the refrigerator compartment 12 or the freezer compartment 13, the ambient temperature, and the amount of storage inside the refrigerator compartment 12 or the freezer compartment 13 for the refrigerator compartment 12 and the freezer compartment 13. The cooling time of the refrigerating chamber 12 or the freezing chamber 13 based on is acquired in advance by experiments or the like and stored in a database.

FIG. 3 is a graph showing an example of predicted cold storage time in the refrigerator compartment 12. As shown in FIG.
As shown in FIG. 3, for example, when the internal temperature of the refrigerator compartment 12 is 5° C. and the ambient temperature of the refrigerator 10 is 16° C., 25° C., and 32° C., the cold storage time for the storage capacity of the refrigerator compartment 12 is obtained. . In the example of FIG. 3, for example, when the internal temperature of the refrigerator compartment 12 is 5° C., the ambient temperature is 25° C., and the storage capacity of the refrigerator compartment 12 is 50%, the cooling time is 8 hours.
Similarly, the predicted cold storage time in the freezer compartment 13 is obtained in advance based on the internal temperature of the freezer compartment 13, the ambient temperature, and the storage capacity of the freezer compartment 13, and a database is created.
In addition, the cooling time means the time until the temperature reaches 10° C. in the case of the refrigerator compartment 12 and the time until the temperature reaches -15° C. in the case of the freezer compartment 13 .
Although this is set in consideration of the influence on the food in the refrigerator, the reference temperature for the cooling time can be changed as appropriate. For example, the reference temperature for the cooling time may be set lower than 10°C or higher than 10°C in the case of the refrigerator compartment 12 . Similarly, the reference temperature for the cooling time may be set lower than -15.degree. C. or higher than -15.degree.

In this case, in the present embodiment, in addition to creating a database of predicted cold storage time information in advance, for example, the cold storage time is generated based on the measured values of the internal temperatures of the refrigerator compartment 12 and the freezer compartment 13. good too.
FIG. 4 is a graph showing an example of generating a predicted cold-storage time based on the actually measured internal temperature of the refrigerator compartment 12 .
In this case, first, the refrigerator control unit 30 uses the sensor unit 33 to detect the temperature inside the refrigerator when the compressor 23 is not driven, such as when the compressor 23 is stopped or during defrosting. The value is sent to the refrigerator management server 40 via the refrigerator communication unit 31 .
The refrigerating compartment temperature information and the freezing compartment temperature information are detected temperature information of the refrigerating compartment 12 or the freezing compartment 13 detected by the sensor unit 33 .

The server control unit 41 of the refrigerator management server 40 calculates a prediction that the temperature inside the refrigerator will rise based on the received change in the detected value of the temperature inside the refrigerator. For example, by predicting the subsequent temperature rise in the refrigerator from changes in the detected value of the temperature in the refrigerator every five minutes, a temperature rise prediction curve is generated as shown in FIG.

The server control unit 41 obtains the current cold storage time in the event of a power failure based on the predicted cold storage time stored in the cold storage management database 44 or the predicted temperature rise curve of the predicted cold storage time calculated by the server control unit 41. . This cooling time is transmitted to the terminal device 50, which will be described later.

Next, the configuration of the terminal device 50 will be described.
The terminal device 50 includes a terminal control section 51 , a terminal communication section 52 and a touch panel 53 .

The terminal control unit 51 is composed of a processor such as a CPU or an MPU that executes programs, and includes a terminal storage unit 54 . The terminal control unit 51 reads a control program stored in the terminal storage unit 54 and controls each unit of the terminal device 50 through cooperation of hardware and software.

A cold storage support application is pre-installed in the terminal device 50 . The cold storage support application 55 is read from the terminal storage unit 54 by the terminal control unit 51 and executed, so that the terminal device 50 notifies the user of the predicted cold storage time.

The terminal storage unit 54 has a storage area for storing programs executed by the terminal control unit 51 and data processed by the terminal control unit 51 . The terminal storage unit 54 stores a control program executed by the terminal control unit 51, setting data related to setting of the terminal device 50, the cooling support application 55, user IDs, and various other data. The terminal storage unit 54 has a nonvolatile storage area. Moreover, the terminal storage unit 54 may include a volatile storage area and configure a work area for the terminal control unit 51 .

The terminal communication unit 52 includes communication hardware conforming to a predetermined communication standard, and under the control of the terminal control unit 51, communicates with devices connected to the global network GN according to the predetermined communication standard. The terminal communication unit 52 communicates with the refrigerator management server 40 according to a predetermined communication standard by the functions of the cold storage support application 55 . The communication standard used by the terminal communication unit 52 is the wireless communication standard.

The touch panel 53 includes a display panel such as a liquid crystal display panel, and a touch sensor provided over or integrally with the display panel. The display panel displays various images under the control of the terminal control unit 51 . The touch sensor detects a touch operation and outputs it to terminal control section 51 . Terminal control unit 51 executes processing corresponding to a touch operation based on an input from the touch sensor.

For example, warning information based on weather information such as a typhoon, power failure risk prediction information, and the like are sent from the power failure prediction server 60 to the terminal device 50 as a push notification. The push notification may be sent to the terminal device 50 on a predetermined date and time, such as the first day of each month.
When the terminal device 50 receives the warning information or the like from the power failure prediction server 60, the terminal control unit 51 executes the cold storage support application 55 to request the refrigerator management server 40 to predict the cold storage time. . In response to this request, the refrigerator management server 40 sends the prediction result of the cold storage time, and the touch panel 53 displays the cold storage time of the refrigerator compartment 12 and the freezer compartment 13 in the event of a power failure.
It should be noted that the cold storage time may be predicted by the user executing the cold storage support application 55 without the push notification.

[1-2. operation etc.]
Next, operations of the refrigerator 10 and the cooling time prediction system 1 according to Embodiment 1 will be described.
First, referring to FIGS. 5 and 6, the operation of predicting the cold storage time based on the database stored in the cold storage management database 44 of the refrigerator management server 40 will be described.

FIG. 5 is an explanatory diagram showing a display example of the touch panel of the terminal device 50. As shown in FIG. FIG. 6 is a timing chart showing an example of estimating the cooling time from the database based on information obtained in advance.
As shown in FIG. 6 , in the present embodiment, refrigerator 10 periodically measures the current internal temperature and ambient temperature and sends the measurement results to refrigerator management server 40 .
Refrigerator management server 40 causes server storage unit 43 to store the sent internal temperature information and ambient temperature information.

Then, as shown in FIG. 6, when a push notification such as alarm information is sent from the power failure prediction server 60, the terminal control unit 51 of the terminal device 50 displays the touch panel 53 for confirming the cooling time when the power failure occurs. Show a confirm button.

Specifically, as shown in FIG. 5A, when a push notification is sent, the terminal control unit 51 of the terminal device 50 activates the cooling support application. When the cold storage support application is started, the touch panel of the terminal device 50 displays the current operation mode of the refrigerator 10 (in FIG. 5, the operation mode is normal mode), and the cold storage time is predicted. confirmation button is displayed.
When the user operates the confirmation button, the terminal control unit 51 causes the touch panel to display a selection icon for the storage amount of the refrigerator 10, as shown in FIG. 5(b).
The user operates the storage amount selection icon to input the storage amount of the refrigerator compartment, and operates the "next" icon. Similarly, the user inputs the storage amount of the freezer compartment (not shown).

When the user operates the confirmation button, the terminal device 50 instructs the refrigerator management server 40 to send the storage amount input by the user.

When the storage amount in the refrigerator is transmitted to the refrigerator management server 40, the server control unit 41 of the refrigerator management server 40 controls based on the storage amount information sent, the internal temperature information stored in advance, and the ambient temperature information. Then, the corresponding predicted cold storage time is extracted from the database stored in the cold storage management database 44 , and the predicted cold storage time is transmitted to the terminal device 50 .

As shown in FIG. 5(c), the terminal device 50 causes the touch panel 53 to display the estimated cooling time transmitted from the refrigerator management server 40. FIG.
In addition, in the case of the refrigerator compartment 12, the predicted cold storage time may be displayed not only by displaying the time from the current time until the temperature reaches 10° C., but also by displaying, for example, the internal temperature after several hours have passed.

In this case, for example, when a frozen PET bottle or the like is placed in the refrigerator compartment 12 or the freezer compartment 13, a proposal may be displayed to the effect that the predicted cold storage time will be extended.
In this case, for example, by allowing the user to select the capacity of the PET bottle, the extension time of the predicted cooling time corresponding to the capacity of the PET bottle may be displayed.

FIG. 7 is a timing chart showing another example of estimating the cooling time from the database based on the information obtained in advance.
In this embodiment, the refrigerator 10 automatically acquires the storage amount in the refrigerator. That is, the refrigerator 10 periodically measures the current internal temperature and ambient temperature, automatically measures the amount of storage in the refrigerator, and sends the measurement results to the refrigerator management server 40 . The storage amount in the refrigerator is measured based on, for example, the illuminance, weight, image, etc. in the refrigerator.
Refrigerator management server 40 causes server storage unit 43 to store the sent internal temperature information and ambient temperature information.

Then, when the user operates the confirmation button by the push notification, the confirmation operation information of the terminal device 50 is sent to the refrigerator management server 40 .
When the confirmation operation information is transmitted to the refrigerator management server 40, the server control unit 41 of the refrigerator management server 40 updates the cold storage management database based on the temperature information, ambient temperature information, and storage amount information stored in advance. From the database stored in 44, the corresponding predicted cooling time is extracted, and the predicted cooling time is transmitted to the terminal device 50.例文帳に追加
The terminal device 50 causes the touch panel 53 to display the predicted cold storage time transmitted from the refrigerator management server 40 .

FIG. 8 is a timing chart showing an example of estimating the cooling time from the database.
As shown in FIG. 8, when a push notification such as alarm information is sent from the power failure prediction server 60, the terminal control unit 51 of the terminal device 50 displays a confirmation button for confirming the cold storage time when the power failure occurs on the touch panel 53. display.
When the user operates the confirmation button, the terminal device 50 instructs the refrigerator 10 to measure the current temperature inside the refrigerator, the ambient temperature, and the amount of storage inside the refrigerator 10 and send the measurement results to the refrigerator management server 40 .

When the measurement result is transmitted to the refrigerator management server 40, the server control unit 41 of the refrigerator management server 40 retrieves the internal temperature information transmitted from the refrigerator 10 from the database stored in the cold insulation management database 44 as described above. , the ambient temperature information, and the storage capacity information in the refrigerator, the corresponding predicted cold preservation time is extracted, and the predicted cold preservation time is transmitted to the terminal device 50 .

The terminal device 50 causes the touch panel 53 to display the predicted cold storage time transmitted from the refrigerator management server 40 .

FIG. 9 is a timing chart showing an example in which the refrigerator 10 predicts the cooling time.
In the present embodiment, a database of predicted cooling time information is stored in the refrigerator storage unit 34 in advance.
As shown in FIG. 9, in the present embodiment, when a push notification such as alarm information is sent from the power failure prediction server 60, the terminal control unit 51 of the terminal device 50 controls the touch panel 53 to keep the cold storage time when the power failure occurs. Display a confirmation button for confirming the
When the user operates the confirmation button, the terminal device 50 instructs the refrigerator 10 to measure the current temperature inside the refrigerator, the ambient temperature, and the storage amount inside the refrigerator.

Based on the measured internal temperature information, ambient temperature information, and internal storage amount information, the refrigerator control unit 30 retrieves the internal temperature information, the ambient temperature information, and the storage amount information from the database stored in the refrigerator storage unit 34. , the corresponding predicted cold-preserved time is extracted, and the predicted cold-preserved time is transmitted to the terminal device 50 .
The terminal device 50 causes the touch panel 53 to display the estimated cooling time transmitted from the refrigerator 10 .

In this case, as shown in FIG. 6, the user inputs the amount of storage in the refrigerator 10 via the terminal device 50 and transmits the storage amount information to the refrigerator 10 so that the refrigerator control unit 30 You may make it extract predicted cold storage time.
In this example, without using the refrigerator management server 40 , the predicted cold storage time can be obtained in the refrigerator 10 and displayed on the terminal device 50 . Therefore, even if there is no facility for connecting to the global network GN such as Wi-Fi (registered trademark), it is possible to obtain the predicted cooling time with short-distance communication facilities such as Bluetooth (registered trademark).

FIG. 10 is a timing chart showing an example in which the terminal device 50 predicts the cooling time.
In this embodiment, the terminal storage unit 54 stores in advance a database of predicted cooling time information.

As shown in FIG. 10, in the present embodiment, when a push notification such as alarm information is sent from the power failure prediction server 60, the terminal control unit 51 of the terminal device 50 sets the cooling time for the touch panel 53 when power failure occurs. Display a confirmation button for confirming the
When the user operates the confirmation button, the terminal device 50 instructs the refrigerator 10 to measure the current temperature inside the refrigerator, the ambient temperature, and the storage amount inside the refrigerator.

The refrigerator control unit 30 sends the measured internal temperature information, ambient temperature information, and internal storage amount information to the terminal device 50 .
Based on the internal temperature information, the ambient temperature information, and the storage amount information sent from the refrigerator 10, the terminal control unit 51 extracts the corresponding predicted cold insulation time from the database stored in the terminal storage unit 54, and predicts it. The stored cooling time is displayed on the touch panel 53.例文帳に追加

In this case, as shown in FIG. 6, the user inputs the amount of storage inside the refrigerator 10 via the terminal device 50, and the terminal control unit 51 controls the temperature inside the refrigerator 10 sent from the refrigerator 10. The predicted cooling time may be extracted based on the information, the ambient temperature information, and the input storage amount information.
In this example, without using the refrigerator management server 40 , the predicted cold storage time can be obtained in the refrigerator 10 and displayed on the terminal device 50 . Therefore, even if there is no facility for connecting to the global network GN such as Wi-Fi (registered trademark), it is possible to obtain the predicted cooling time with short-distance communication facilities such as Bluetooth (registered trademark).

Next, the operation when the refrigerator management server 40 predicts the cooling time based on the measured value will be described.
FIG. 11 is a timing chart showing an example of estimating the cooling time based on actual measurements.
As shown in FIG. 11 , when a push notification such as alarm information is sent from the power failure prediction server 60 , the terminal control unit 51 of the terminal device 50 displays a confirmation button for confirming the cooling time in the event of power failure on the touch panel 53 . display.
When the user operates the confirmation button, the terminal device 50 instructs the refrigerator management server 40 to send the predicted cold storage time.

The refrigerator management server 40 is sent in advance the detected value of the internal temperature when the compressor 23 is stopped from the refrigerator 10 to the refrigerator management server 40. Based on the internal temperature sent from the refrigerator 10, a predicted temperature rise curve for the predicted cold storage time is calculated, the cold storage time in the event of a power failure at the present time is calculated, and the predicted cold storage time is sent to the terminal device 50. Send.

The terminal device 50 causes the touch panel 53 to display the predicted cold storage time transmitted from the refrigerator management server 40 .
In this case, as described above, the internal temperature after several hours may be displayed, or a proposal to extend the predicted cold storage time may be displayed.

Although the operation for estimating the cooling time based on the actual measurement has been described, the present disclosure is not limited to this.
For example, the refrigerator management server 40 does not acquire the internal temperature information of the refrigerator 10 in advance, but when the user operates the confirmation button, the compressor 23 stored in advance in the refrigerator storage unit 34 stops. A detected value of the temperature inside the refrigerator in the state where the refrigerator is being operated may be sent to the refrigerator management server 40 . In this case, it is preferable to send to the refrigerator management server 40 the latest detected value of the internal temperature before the user operates the confirmation button, that is, the detected value of the internal temperature when the compressor 23 is stopped. At least two internal temperature detection values are required to be sent to the refrigerator management server 40 . More than two detected values of internal temperature may be sent to refrigerator management server 40 . Also, the detected value of the internal temperature may be stored in the temperature sensor.
Further, as in the case of predicting the cold storage time using the database described above, it is possible to predict the cold storage time not only by the refrigerator management server 40 but also by the refrigerator 10 or the terminal device 50 .

[1-3. effects, etc.]
As described above, in the present embodiment, when the refrigerator 10 is equipped with the cooler 20 for cooling the inside of the refrigerator, and the occurrence of a power failure is predicted in advance, the preset temperature inside the refrigerator 10 or the actually measured temperature is reduced. A server control unit 41 (control unit) that obtains a predicted cold storage time in the event of a power failure based on the internal temperature and notifies the user.
As a result, the server control unit 41 obtains the estimated cold storage time in the event of a power failure and notifies the user of this, so that the cold storage status in the refrigerator 10 when the power failure occurs can be grasped. You can manage food in the warehouse.

Further, in the present embodiment, the server control unit 41 (control unit) has a database in which the cooling time is determined based on the preset internal temperature and the ambient temperature. Calculate the predicted cold storage time in the case of
This makes it possible to easily predict the cooling time based on the database.

Further, in the present embodiment, the server control unit 41 (control unit) acquires the actually measured internal temperature of the refrigerator 10 when cooling is stopped, and the server control unit 41 controls the acquired internal temperature Based on the above, the predicted cold storage time in the event of a power failure is obtained.
As a result, it is possible to predict the cooling time in the event of a power failure based on the measured internal temperature.

In addition, in the present embodiment, the server control unit 41 (control unit) acquires the ambient temperature of the refrigerator 10 and the amount of storage inside the refrigerator 10, and based on the temperature inside the refrigerator 10, the ambient temperature, and the amount of storage, Calculate the predicted cold storage time in the case of
This makes it possible to predict the cooling time in the event of a power failure.

Further, in the present embodiment, a terminal device 50 capable of communicating with the refrigerator 10 and the refrigerator management server 40 is provided, and the terminal device 50 displays the predicted cold storage time obtained by the server control unit 41 to notify the user of the predicted cold storage time. .
As a result, the terminal device 50 can notify the user of the predicted cold storage time at the time of power failure.

(Embodiment 2)
Next, Embodiment 2 of the present invention will be described.
[2-1. Constitution]
In the present embodiment, the configurations of the refrigerator 10 and the cooling time prediction system 1 are the same as those in the first embodiment. , are denoted by the same reference numerals, and the description thereof is omitted.
In Embodiment 1, the cooling time before power failure is predicted, whereas in this embodiment, the cooling time during power failure is predicted.

Refrigerator management server 40 is provided with cold insulation management database 44 as in the first embodiment, and cold insulation management database 44 stores predicted cold insulation time information of refrigerator 10 in database form.
In Embodiment 1, the server control unit 41 obtains the predicted cold storage time based on the internal temperature information, the ambient temperature information, and the internal capacity information of the refrigerator 10. It is difficult to obtain information on
Therefore, in the present embodiment, for example, a battery that can drive only the sensor unit 33 and the refrigerator communication unit 31 of the refrigerator 10 is provided. I am trying to send. Then, the server control unit 41 predicts the cold storage time from the cold storage management database 44 based on the cold storage temperature information.

Further, as in the first embodiment, the cold storage time may be generated based on the measured values of the internal temperatures of the refrigerator compartment 12 and the freezer compartment 13 .
In this case, first, the refrigerator control unit 30 uses the sensor unit 33 to detect the temperature inside the refrigerator when the compressor 23 is not driven, such as when the compressor 23 is stopped or during defrosting. The value is sent to the refrigerator management server 40 via the refrigerator communication unit 31 .
The server control unit 41 of the refrigerator management server 40 calculates a prediction that the temperature inside the refrigerator will rise based on the received change in the detected value of the temperature inside the refrigerator.

In this case, in the present embodiment, since the power is out, the refrigerator 10 is currently stopped, and the internal temperature of the refrigerator 10 cannot be obtained.
Therefore, when predicting the cooling time based on the measured value of the internal temperature, the cooling time can be predicted based on the measured value obtained before the power failure. Furthermore, as described above, in the event of a power failure, a battery may be used to transmit the measured value of the internal temperature to the refrigerator management server 40 .

Further, during a power failure, refrigerator management server 40 is in a state where it cannot determine whether refrigerator 10 is in power failure.
Therefore, for example, the refrigerator management server 40 communicates with the refrigerator 10 at predetermined time intervals, and if there is a response, it can be determined that there is no power outage.
Similarly, when predicting the cooling time based on the measured value, it may be determined that there is a power outage when the measured value of the internal temperature is not transmitted from the refrigerator 10 for a certain period of time.
Furthermore, the power failure state may be transmitted to the refrigerator management server 40 by the user operating the terminal device 50 .

[2-2. operation etc.]
Next, the operation of refrigerator 10 and cooling time prediction system 1 according to Embodiment 2 will be described.
First, with reference to FIG. 12, the operation of predicting the cold storage time based on the database stored in the cold storage management database 44 of the refrigerator management server 40 will be described.

FIG. 12 is a timing chart showing an example of estimating the cooling time from the database.
As shown in FIG. 12, the refrigerator 10 periodically measures the current internal temperature and ambient temperature, automatically measures the amount of storage in the refrigerator, and sends the measurement results to the refrigerator management server 40. .
The refrigerator management server 40 causes the server storage unit 43 to store the sent internal temperature information, ambient temperature information, and storage amount information.

When the user operates the confirmation button of the terminal device 50 during a power outage, the confirmation operation information of the terminal device 50 is sent to the refrigerator management server 40 .

When the confirmation operation information is transmitted to the refrigerator management server 40, the server control unit 41 of the refrigerator management server 40 retrieves the internal temperature information and the ambient temperature information transmitted from the refrigerator 10 from the database stored in the cold storage management database 44. , based on the storage amount information, the corresponding predicted cold storage time is extracted.

In this case, the internal temperature information, the ambient temperature information, and the storage amount information are not newly sent from the refrigerator 10 because of the power failure. Cooling time is predicted based on the information.
As described above, for example, the refrigerator management server 40 communicates with the refrigerator 10 at predetermined time intervals, and if there is no response, it can be determined that there is a power outage. Therefore, the refrigerator management server 40 stores the time when the power failure occurs, and calculates the remaining cold storage time by subtracting the time from the time of power failure to the time when the confirmation button is operated by the user from the predicted cold storage time.

The terminal device 50 causes the touch panel 53 to display the remaining cooling time transmitted from the refrigerator management server 40 . At the same time, the internal temperature is displayed.
In this case, as in the first embodiment, the internal temperature after several hours may be displayed, or a proposal to extend the predicted cold storage time may be displayed.

Next, the operation when the refrigerator management server 40 predicts the cooling time based on the measured value will be described.
FIG. 13 is a timing chart showing the operation when estimating the cooling time based on actual measurements.
In the present embodiment, for example, a battery that can drive only the sensor unit 33 and the refrigerator communication unit 31 of the refrigerator 10 is provided. It is configured. It should be noted that a temperature sensor other than the refrigerator, which is used during a power outage, may transmit the measured value of the temperature inside the refrigerator to the refrigerator management server 40 . In this case, the temperature sensor used during the power outage is driven by a battery and has the same functions as the sensor unit 33 and refrigerator communication unit 31 of the refrigerator 10 .
As shown in FIG. 13 , when the user operates the confirmation button of the terminal device 50 , the terminal device 50 instructs the refrigerator management server 40 to send the predicted cold storage time.

The refrigerator management server 40 calculates a predicted temperature rise curve of the predicted cold keeping time based on the detected value of the temperature inside the refrigerator during the power outage sent in advance to obtain the predicted cold keeping time.
Refrigerator management server 40 then calculates the remaining cold storage time based on the predicted cold storage time and transmits the calculated remaining cold storage time to terminal device 50 .

The terminal device 50 causes the touch panel 53 to display the remaining cold storage time and/or the internal temperature transmitted from the refrigerator management server 40 .

Next, the operation for estimating the cooling time based on the actually measured value will be described.
FIG. 14 is a timing chart showing an example of estimating the cooling time based on actual measurements.
In the present embodiment, for example, a battery capable of driving the refrigerator control unit 30, the sensor unit 33, and the refrigerator communication unit 31 of the refrigerator 10 is provided. 40 can be sent.
It should be noted that a configuration may be adopted in which a temperature sensor used during a power failure, separate from the refrigerator 10 , can transmit the measured value of the temperature inside the refrigerator to the refrigerator management server 40 . In this case, the temperature sensor used during power outage has the same functions as refrigerator control unit 30 , sensor unit 33 , and refrigerator communication unit 31 of refrigerator 10 .

As shown in FIG. 14 , when the user operates the confirmation button of the terminal device 50 , the current inside temperature is measured from the terminal device 50 to the refrigerator 10 , and the inside temperature information including the measurement result is sent to the refrigerator management server 40 . instruct to send. This refrigerator temperature information also includes the result of measuring the refrigerator interior temperature during the power failure before the user operates the confirmation button. At least two internal temperature measurement results are required to be sent to the refrigerator management server 40 . More than two results of measuring the temperature inside the refrigerator may be sent to the refrigerator management server 40 . In this case, the refrigerator storage unit 34 stores the temperature inside the refrigerator during the power outage. When the refrigerator control unit 30 is not driven, the sensor unit 33 may have a function of storing the temperature inside the refrigerator during power failure.

When the internal temperature information is transmitted to the refrigerator management server 40, the server control unit 41 of the refrigerator management server 40 calculates a predicted temperature rise curve for the predicted cold storage time based on the internal temperature information, and determines the predicted cold storage time. Based on the estimated cold keeping time, the remaining cold keeping time is calculated and transmitted to the terminal device 50.例文帳に追加
Further, when the user operates the confirmation button, the terminal device 50 may instruct the refrigerator 10 to measure the current temperature inside the refrigerator 10 and transmit the measurement result to the refrigerator management server 40 . In this case, when the measurement result is transmitted to the refrigerator management server 40, the server control unit 41 of the refrigerator management server 40 determines the temperature of the predicted cold storage time based on the previously sent detection value of the temperature inside the refrigerator during the power outage. A rising predicted curve is calculated, a predicted cold-storage time is obtained, and the remaining cold-storage time is calculated based on the predicted cold-storage time and transmitted to the terminal device 50.例文帳に追加
The terminal device 50 causes the touch panel 53 to display the remaining cold storage time and/or the internal temperature transmitted from the refrigerator management server 40 .

Next, the operation when the refrigerator 10 predicts the cooling time based on the measured value will be described.
FIG. 15 is a timing chart showing an example in which the refrigerator 10 predicts the cooling time based on actual measurements.
In the present embodiment, for example, a battery that can drive the refrigerator control unit 30, the sensor unit 33, and the refrigerator communication unit 31 of the refrigerator 10 is provided. The configuration is such that the measured values can be transmitted to the terminal device 50 .
It should be noted that, apart from the refrigerator 10 , a configuration may be adopted in which a temperature sensor used during a power failure can transmit the remaining cold insulation time and/or the actually measured value of the temperature inside the refrigerator to the terminal device 50 . In this case, the temperature sensor used during power outage is driven by a battery and has the same functions as refrigerator control section 30 , sensor section 33 and refrigerator communication section 31 of refrigerator 10 .

As shown in FIG. 15, when the user operates the confirmation button of the terminal device 50, the current inside temperature is measured from the terminal device 50 to the refrigerator 10, and based on the inside temperature information including the measurement result, a predicted cold insulation Prompt to find the time and/or remaining cool down time.
This refrigerator temperature information also includes the result of measuring the refrigerator interior temperature during the power failure before the user operates the confirmation button. At least two results of measuring the internal temperature are required. More than two results of measuring the internal temperature may be used. In this case, the refrigerator storage unit 34 stores the internal temperature during the power outage. When the refrigerator control unit 30 is not driven, the sensor unit 33 may have a function of storing the temperature inside the refrigerator during power failure.
Refrigerator control unit 30 calculates a predicted temperature rise curve for the predicted cold insulation time based on the measured internal temperature, obtains the predicted cold insulation time, calculates the remaining cold insulation time based on the predicted cold insulation time, and outputs the temperature to the terminal. Send to device 50 .
The terminal device 50 causes the touch panel 53 to display the remaining cooling time and/or the internal temperature transmitted from the refrigerator 10 .

In this example, the remaining cold storage time in the refrigerator 10 can be obtained and displayed on the terminal device 50 without using the refrigerator management server 40 . Therefore, even if equipment that connects to the global network GN such as Wi-Fi (registered trademark) cannot be used due to a power outage, for example, as long as there is short-range communication equipment such as Bluetooth (registered trademark), the remaining cooling time and / or You can get the inside temperature.

Next, the operation when the terminal device 50 predicts the cooling time based on the measured value will be described.
FIG. 16 is a timing chart showing an example in which the terminal device 50 predicts the cooling time based on actual measurements.
In the present embodiment, for example, a battery capable of driving the sensor unit 33 and the refrigerator communication unit 31 of the refrigerator 10 is provided. It's becoming
It should be noted that a configuration may be adopted in which a temperature sensor used during a power outage, separate from the refrigerator 10 , can transmit the actually measured value of the temperature inside the refrigerator to the terminal device 50 . In this case, the temperature sensor used during power outage has the same functions as refrigerator control unit 30 , sensor unit 33 , and refrigerator communication unit 31 of refrigerator 10 .

As shown in FIG. 16 , when the user operates the confirmation button of the terminal device 50 , the current internal temperature is measured from the terminal device 50 to the refrigerator 10 , and the internal temperature information including the measurement result is transmitted to the terminal device 50 . instruct to do so.
This refrigerator temperature information also includes the result of measuring the refrigerator interior temperature during the power failure before the user operates the confirmation button. At least two chamber temperature measurement results are required to be sent to the terminal device 50 . More than two results of measuring the temperature inside the refrigerator may be sent to the terminal device 50 . In this case, the refrigerator storage unit 34 stores the internal temperature during the power outage. When the refrigerator control unit 30 is not driven, the sensor unit 33 may have a function of storing the temperature inside the refrigerator during power failure.
Based on the internal temperature information sent from the refrigerator 10, the terminal control unit 51 calculates a predicted temperature rise curve for the predicted cold preservation time, obtains the predicted cold preservation time, and calculates the remaining cold preservation time based on the predicted cold preservation time. calculate.
The terminal device 50 causes the touch panel 53 to display the calculated remaining cooling time and/or the internal temperature.

[2-3. effects, etc.]
As described above, in the present embodiment, the refrigerator 10 equipped with the cooler 20 for cooling the inside of the refrigerator, and in the event of a power failure, a , and a server control unit 41 (control unit) that obtains an estimated cold storage time and informs the user.
As a result, the server control unit 41 obtains the remaining cooling time during the power failure and informs the user of this, so that the cooling status inside the refrigerator 10 at the time of the power failure can be grasped. Can manage food.

Further, in the present embodiment, the server control unit 41 (control unit) has a database in which the cooling time is determined based on the preset internal temperature and the ambient temperature. Find the remaining cooling time inside.
This makes it possible to easily predict the cooling time based on the database.

Further, in the present embodiment, the server control unit 41 (control unit) acquires the actually measured internal temperature of the refrigerator 10 during power failure, and the server control unit 41 detects the power failure based on the acquired internal temperature. Find the remaining cooling time inside.
As a result, it is possible to predict the cooling time during a power failure based on the measured value of the internal temperature.

In addition, in the present embodiment, the server control unit 41 (control unit) acquires the ambient temperature of the refrigerator 10 and the amount of storage inside the refrigerator 10, and based on the temperature inside the refrigerator 10, the ambient temperature, and the amount of storage, Find the remaining cooling time inside.
This makes it possible to predict the cooling time during power failure.

In addition, in the present embodiment, the refrigerator management server 40 that can communicate with the refrigerator 10 is provided, the refrigerator includes a sensor unit that detects the temperature inside the refrigerator, and a battery that energizes the sensor unit in the event of a power failure. At this time, the internal refrigerator temperature is transmitted to the refrigerator management server 40. - 特許庁
This makes it possible to predict the cooling time during a power failure.

Further, in the present embodiment, a terminal device 50 capable of communicating with the refrigerator 10 and the refrigerator management server 40 is provided, and the terminal device 50 displays the predicted cold storage time obtained by the server control unit 41 to notify the user of the predicted cold storage time. .
As a result, the terminal device 50 can notify the user of the predicted cold storage time at the time of power failure.

In addition, Embodiment 1 and Embodiment 2 have been described as examples of the technology disclosed in the present application. However, the technology in the present disclosure is not limited to this, and can also be applied to embodiments with modifications, replacements, additions, omissions, and the like.

As described above, the cold storage time prediction system according to the present invention can confirm the cold storage time at the time of power failure, and can be suitably used as a cold storage time prediction system that can manage food in the refrigerator based on the cold storage time. It is possible.

1 refrigerating time prediction system 10 refrigerator 11 housing 12 refrigerating chamber 13 freezing chamber 14 partition wall 15 door 16 drawer 17 duct 18 refrigerating outlet 19 freezing outlet 20 cooler 21 cooling fan 22 damper 23 compressor 30 refrigerator control unit 31 refrigerator communication unit 32 cooling unit 33 sensor unit 34 refrigerator storage unit 35 refrigerator temperature sensor 36 freezer temperature sensor 37 ambient temperature sensor 40 refrigerator management server 41 server control unit 42 server communication unit 43 server storage unit 44 cold storage management database 50 terminal Apparatus 51 Terminal control unit 52 Terminal communication unit 53 Touch panel 54 Terminal storage unit 55 Cooling support application 60 Power failure prediction server GN global network

Claims (6)

a refrigerator equipped with a cooler for cooling the inside of the refrigerator;
a control unit that, when the occurrence of a power failure is predicted in advance, obtains the predicted cold storage time in the event of a power failure based on the set internal temperature of the refrigerator or the actually measured internal temperature, and notifies the user of the predicted cold storage time. Characteristic cooling time prediction system. The control unit has a database in which the cooling time based on the set internal temperature is obtained in advance,
2. The cold storage time prediction system according to claim 1, wherein the control unit obtains a predicted cold storage time in the event of a power failure based on the database. The control unit obtains an actually measured temperature inside the refrigerator in a state where cooling of the refrigerator is stopped,
2. The cold storage time prediction system according to claim 1, wherein the control unit obtains a predicted cold storage time in the event of a power failure based on the obtained internal temperature. 2. The control unit acquires the ambient temperature and the amount of storage inside the refrigerator, and obtains the predicted cold storage time based on the temperature inside the refrigerator, the ambient temperature, and the amount of storage. Alternatively, the cooling time prediction system according to claim 2. A refrigerator management server capable of communicating with the refrigerator,
The cooling time prediction system according to any one of claims 1 to 4, wherein the control unit is a server control unit of the refrigerator management server. A terminal device capable of communicating with the refrigerator and the refrigerator management server,
6. The cold storage time prediction system according to claim 5, wherein the terminal device notifies the user of the predicted cold storage time obtained by the server control unit by displaying the predicted cold storage time.

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