JP2024034238A - Temperature management method, information processing system, program and information processor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a temperature management method, etc. capable of issuing a warning while considering a defrosting operation of a showcase.

SOLUTION: In a temperature management method, temperature data in a showcase measured by a temperature sensor provided in the showcase is acquired. On the basis of the acquired temperature data, when the temperature in the showcase exceeds a first threshold value and a determination that defrosting operation of the showcase is not being executed is made, a warning is output. On the basis of the acquired temperature data, when the temperature in the showcase exceeds the first threshold value and a determination that the defrosting operation of the showcase is being executed is made, the warning is not output.

SELECTED DRAWING: Figure 9

COPYRIGHT: (C)2024,JPO&INPIT

Description

Application for application of Article 30, Paragraph 2 of the Patent Act Published on the website of Iris Ohyama Co., Ltd. on December 7, 2021 (https://www.irisohyama.co.jp/led/houjin/liconex/ haccp/)

The present invention relates to a temperature management method, an information processing system, a program, and an information processing device.

2. Description of the Related Art Facilities such as supermarkets and convenience stores are equipped with freezer-refrigerated showcases and refrigerator-freezers for displaying or preserving products that require freezing or refrigeration. Managers of these freezer-refrigerated showcases and freezer-refrigerators need to manage whether the internal temperature is maintained within an appropriate temperature range and whether the devices are operating normally. In order to manage the showcase, it is a heavy burden for the manager to check the temperature inside each warehouse to be managed multiple times every day. Techniques have been proposed to reduce the burden of temperature management on administrators.

Patent Document 1 discloses a freezing and refrigeration equipment management system that allows an external management company to collectively manage food freezing and refrigeration equipment. In the freezing and refrigeration equipment management system of Patent Document 1, when a temperature sensor attached to the freezing and refrigeration equipment outputs an abnormal value, a management device operated by a management company records the temperature history for a certain period before the abnormal value was output. An alarm signal is sent to the corresponding user along with the data.

JP2002-228340A

However, the freezing and refrigeration equipment management system described in Patent Document 1 has a problem in that the defrosting operation of the showcase is not taken into account when outputting the warning. In the frozen and refrigerated showcase, a defrosting operation is performed to remove frost that has adhered to the inside of the showcase. During the defrosting operation, the temperature inside the showcase is maintained at a higher temperature than during normal operation. A technology is desired that can detect temperature abnormalities and issue a warning in consideration of the defrosting operation of the showcase.

An object of the present disclosure is to provide a temperature management method etc. that realizes issuing a warning in consideration of the defrosting operation of the showcase.

A temperature management method according to an aspect of the present disclosure acquires temperature data in the showcase measured by a temperature sensor provided in the showcase, and determines the temperature in the showcase based on the acquired temperature data. If the temperature in the showcase exceeds the first threshold and it is determined that the showcase is not being defrosted, a warning is output, and based on the acquired temperature data, the temperature in the showcase exceeds the first threshold and the If it is determined that the showcase is being defrosted, no warning is output.

According to the present disclosure, a warning can be issued in consideration of the defrosting operation of the showcase.

FIG. 1 is a schematic diagram of an information processing system. FIG. 2 is a block diagram showing a configuration example of a management device. It is a figure which shows the example of the content of the information memorize|stored in management DB. It is a figure which shows the example of the content of the information memorize|stored in temperature DB. FIG. 2 is a block diagram showing a configuration example of a control device. FIG. 2 is a block diagram showing a configuration example of a temperature sensor. It is a figure showing an example of arrangement of a temperature sensor. FIG. 3 is an explanatory diagram illustrating a defrosting operation estimation method. 3 is a flowchart illustrating an example of a procedure for outputting warning information. 3 is a flowchart illustrating an example of a detailed procedure of an operation state determination process. It is an explanatory diagram showing an outline of a learning model of a 2nd embodiment. 12 is a flowchart illustrating an example of a detailed procedure for determining whether a defrosting operation is to be performed. 12 is a flowchart illustrating an example of a measurement interval changing process procedure in the third embodiment. 12 is a flowchart illustrating an example of a processing procedure executed by an information processing system according to a fourth embodiment. It is a block diagram showing an example of composition of a temperature sensor of a 5th embodiment. 3 is a flowchart illustrating an example of a temperature data correction processing procedure.

The present disclosure will be specifically described with reference to drawings showing embodiments thereof.

(First embodiment)
FIG. 1 is a schematic diagram of an information processing system 100. The information processing system 100 is a system that manages the temperature of a showcase 6 installed in a facility such as a supermarket or a convenience store, for example. The information processing system 100 includes the management device 1 as a main device. The management device 1 is connected to a network N such as the Internet. Further, a control device 2, a user terminal 3, and a provider terminal 4 are connected to the network N. The control device 2 is communicably connected to a temperature sensor 5 attached to the showcase 6.

The management device 1 is a device capable of various information processing and transmission/reception of information, and is, for example, a server computer, a personal computer, a quantum computer, or the like. The management device 1 corresponds to an information processing device for implementing a temperature management method. The management device 1 acquires temperature data in the showcase 6 measured by the temperature sensor 5 via the control device 2 . The management device 1 monitors the temperature status of the showcase 6 based on the temperature data, and outputs a warning to the user terminal 3 and provider terminal 4 if an abnormality is detected. The management device 1 realizes a temperature management service for supporting temperature management work of the showcase 6.

The showcase 6 is for displaying products such as foods at a store, for example. The showcase 6 is for refrigerating or freezing and refrigerating, and has a function of keeping products warm. The number of showcases 6 provided in the facility may be one or three or more. A temperature sensor 5 is attached to the showcase 6.

The temperature sensor 5 measures (detects) the temperature inside the showcase 6 at appropriate measurement intervals, and transmits information regarding the measured temperature to the control device 2. The showcase 6 may include a plurality of temperature sensors 5.

The control device 2 controls the operation of the temperature sensor 5 and transmits temperature data received from the temperature sensor 5 to the management device 1. The control device 2 is provided, for example, in the same facility where the showcase 6 including the temperature sensor 5 is installed.

The user terminal 3 and the provider terminal 4 are information processing terminals that perform various information processing and transmit/receive information, and are, for example, a personal computer, a smartphone, a tablet terminal, or the like. A user who enjoys the temperature management service can obtain information provided from the management device 1 using the user terminal 3. A service provider who provides temperature management services can obtain information provided from the management device 1 using the provider terminal 4.

The number of facilities to be managed by the information processing system 100 may be two or more, and the number of control devices 2 may be two or more. Further, the number of user terminals 3 may be two or more. The management device 1 and the user terminal 3 or provider terminal 4 are not limited to separate devices, but may be a single common processing device.

FIG. 2 is a block diagram showing a configuration example of the management device 1. As shown in FIG. The management device 1 includes a control section 11, a storage section 12, and a communication section 13. The management device 1 may be configured to include multiple computers and perform distributed processing, may be realized by multiple virtual machines installed in one server, or may be realized using a cloud server. good.

The control unit 11 includes a processor using one or more CPUs (Central Processing Units), GPUs (Graphics Processing Units), and the like. The control unit 11 uses a built-in memory such as a ROM (Read Only Memory) or a RAM (Random Access Memory), a clock, a counter, etc. to control each component and execute processing.

The storage unit 12 includes nonvolatile memory such as a hard disk, flash memory, and solid state drive (SSD). The storage unit 12 may be an external storage device connected to the management device 1. The storage unit 12 stores various programs and data referenced by the control unit 11. The storage unit 12 of this embodiment includes a program 1P for causing a computer to execute processes related to abnormality detection and warning output in the showcase 6, and a management DB (Data Base) as data necessary for executing this program 1P. ) 121 and temperature DB 122. The storage unit 12 may further store a learning model 123. The learning model 123 will be described in detail in other embodiments.

A program (program product) including the program 1P may be provided by a non-temporary recording medium 1A on which the program is readably recorded. The storage unit 12 stores a program read from the recording medium 1A by a reading device (not shown). The recording medium 1A is, for example, a magnetic disk, an optical disk, a semiconductor memory, or the like. Alternatively, the program may be downloaded from an external server connected to a communication network and stored in the storage unit 12. Program 1P may be a single computer program or may be composed of multiple computer programs, and may be executed on a single computer or multiple computers interconnected by a communication network. good.

The communication unit 13 includes a communication module for communicating with an external device via the network N. The control unit 11 transmits and receives data to and from each of the control device 2, user terminal 3, and provider terminal 4 through the communication unit 13.

The configuration of the management device 1 is not limited to the above-described example, and may include, for example, an operation section for accepting user operations, a display section for displaying various information, and the like.

FIG. 3 is a diagram showing an example of the content of information stored in the management DB 121. The management DB 121 is a database that stores management information for managing the temperature of the showcase 6. The management DB 121 stores records in which information such as temperature sensor information, control device information, user terminal information, provider terminal information, upper limit temperature, warning temperature, and allowable time are linked.

The temperature sensor information is identification information for identifying the temperature sensor 5, and includes, for example, the IP address of the temperature sensor 5, the device ID, and the like. The control device information is identification information for identifying the temperature sensor 5 and the control device associated with the showcase 6 including the temperature sensor 5.

The user terminal information and the provider terminal information are identification information for identifying the user terminal 3 and the provider terminal 4, respectively, which are associated with the temperature sensor 5 and the showcase 6 that includes the temperature sensor 5. The user terminal 3 associated with the temperature sensor 5 and the showcase 6 is the user terminal 3 of the user of the management service related to the temperature sensor 5, and the user terminal 3 is the user terminal 3 of the user of the management service related to the temperature sensor 5. This refers to the user terminal 3 to which the warning information is output in the event of an error. The provider terminal 4 associated with the temperature sensor 5 and the showcase 6 is the provider terminal 4 of a service provider of a management service related to the temperature sensor 5, and the provider terminal 4 is a provider terminal 4 of a service provider of a management service related to the temperature sensor 5. refers to the provider terminal 4 to which warning information is output when there is an abnormality).

The upper limit temperature is a first threshold value used to detect an abnormality of the temperature sensor 5, and is the upper limit value of the control temperature range in normal operation of the temperature sensor 5. The upper limit temperature can be set in a range of 5°C to 10°C, for example.

The warning temperature is a second threshold value used to detect an abnormality of the temperature sensor 5, and is the upper limit value of the temperature range in the defrosting operation of the temperature sensor 5. The warning temperature can be set in a range of 11°C to 20°C, for example.

The allowable time is a threshold value used to detect an abnormality in the temperature sensor 5, and is the time allowed for the temperature data of the showcase 6 that has undergone defrosting to return to the controlled temperature range after it deviates from the controlled temperature range. It is.

The management DB 121 further includes showcase information that is identification information for identifying the showcase 6 in which the temperature sensor 5 is installed, facility information that is identification information for identifying the facility where the showcase 6 is installed, and management temperature. A lower limit temperature or the like corresponding to the lower limit of the band may be stored.

Management information is collected, for example, when a user uses the information processing system 100 for the first time, by accepting a user's registration operation using a registration screen provided by the management device 1 using a user terminal. Ru. The management device 1 stores management information for each of the plurality of temperature sensors 5 included in the information processing system 100. Management information may be updated at any timing. For example, the user can change the upper limit temperature, warning temperature, permissible time, etc. at any timing.

FIG. 4 is a diagram showing an example of the content of information stored in the temperature DB 122. The temperature DB 122 is a database that stores information regarding temperature data measured by the temperature sensor 5. For example, the temperature DB 122 stores records in chronological order in which temperature sensor information, temperature data (temperature measurement value), and information such as measurement date and time are linked using a measurement value ID for identifying temperature data as a key. has been done. Every time the management device 1 acquires temperature data through the control device 2, it stores it in the temperature DB 122. The contents of the temperature DB 122 are updated at any time.

FIG. 5 is a block diagram showing a configuration example of the control device 2. As shown in FIG. The control device 2 includes a control section 21 , a storage section 22 , a first communication section 23 , and a second communication section 24 .

The control unit 21 is composed of a CPU, etc., and controls the entire control device 2 using built-in memories such as ROM and RAM. The storage unit 22 includes, for example, a nonvolatile storage device such as a flash memory. The storage unit 22 stores various programs and data referenced by the control unit 21.

The first communication unit 23 includes a communication module for performing processing related to communication via the network N. The control unit 21 transmits and receives data to and from the management device 1 through the first communication unit 23.

The second communication unit 24 includes a communication module for performing processing related to communication using short-range wireless communication such as Bluetooth (registered trademark), WiFi (registered trademark), and Low Energy. The control unit 21 transmits and receives data to and from the temperature sensor through the second communication unit 24. Note that the control device 2 and the second communication unit 24 may realize communication with the temperature sensor 5 through a relay device (not shown) for relaying communication.

The configuration of the control device 2 is not limited to the above-mentioned example, and may include, for example, an operation section for accepting user operations, a display section for displaying various information, and the like.

The control device 2 may communicate with the temperature sensor 5 through a relay device for relaying communication. Note that if the temperature sensor 5 itself has a communication function with the management device 1, the control device 2 may not be provided.

FIG. 6 is a block diagram showing a configuration example of the temperature sensor 5. As shown in FIG. The temperature sensor 5 includes a control section 51 , a communication section 52 , a temperature detection section 53 , and a power supply section 54 .

The control unit 51 is composed of a CPU, etc., and controls the entire control device 2 using built-in memories such as ROM and RAM. The communication unit 52 includes a communication module for performing processing related to communication with the management device 1. The control unit 51 transmits and receives data to and from the management device 1 through the communication unit 52.

The temperature detection unit 53 is a part for demonstrating the temperature detection function of the temperature sensor 5, and includes, for example, a thermistor. The resistance value of a thermistor changes depending on the surrounding temperature. Based on the resistance value of the temperature detection section 53, the temperature of the environment in which the temperature sensor 5 is placed can be measured. The control unit 51 acquires information indicating the temperature through the temperature detection unit 53 in accordance with the measurement interval instruction transmitted from the control device 2 . The temperature detection unit 53 of this embodiment is provided outside the casing 55 (see FIG. 7) via a lead wire from the casing 55 (see FIG. 7) in which other components of the temperature sensor 5 are housed.

The power supply section 54 supplies power to each functional element of the temperature sensor 5. The power supply unit 54 is connected to a commercial power source and can supply power obtained from the commercial power source.

Further, the power supply section 54 of this embodiment includes a charging section 541 and a self-power generation section 542. The charging section 541 and the self-power generation section 542 are connected via a charging circuit (lead line) not shown. The charging unit 541 includes, for example, a storage battery such as a lithium ion battery, and stores electric power. The self-power generation unit 542 supplies electric power by generating electricity by itself. The charging unit 541 charges the power supplied from the self-power generation unit 542.

The self-power generation section 542 of this embodiment includes a Peltier element. The Peltier element includes a first electrode 543 and a second electrode 544 (see FIG. 7). The first electrode 543 and the second electrode 544 are joined via a joining part 545. In a Peltier element, a potential difference (voltage) is generated between the electrodes due to a temperature difference between one surface and the other surface provided with each electrode. The self-power generation section 542 of this embodiment is provided outside the housing 55, similarly to the temperature detection section 53. By arranging the self-power generation section 542 at a position where a temperature difference occurs within the showcase 6, the self-power generation function can be exhibited.

FIG. 7 is an explanatory diagram illustrating an example of the arrangement position of the temperature sensor 5. Note that the region indicated by the upper dot-dashed line in FIG. 7 is an enlarged version of the region indicated by the lower dot-dashed line. The showcase 6 includes a rectangular parallelepiped main body 61, a top portion 62, a power supply portion 63 provided above the top portion 62, and the like. A plurality of shelves arranged in the vertical direction are provided inside the main body 61, and products are displayed on the shelves. The power supply unit 63 is connected to the power supply unit 54 of the temperature sensor 5 and supplies power to the temperature sensor 5. The power supply unit 63 converts, for example, commercial AC power into DC power suitable for driving the temperature sensor 5. The installation position of the power supply section 63 is not particularly limited. The main body 61 may also include a cooler that cools the air within the main body 61, a display device that displays predetermined information, a sound generator that generates sound, and the like.

A cold air discharge port 64 is provided on the lower surface of the tip of the top portion 62. Cold air cooled by the cooler is discharged into the main body 61 through the cold air discharge port 64 . A defrosting heater 65 for defrosting the showcase 6 is provided near the cold air outlet 64. The defrosting heater 65 operates in response to the defrosting operation of the showcase 6, and hot air is discharged into the main body 61 from an opening (not shown) of the defrosting heater 65.

In the example shown in FIG. 7 , the housing 55 of the temperature sensor 5 is arranged on the top surface of the ceiling 62 . The temperature detection section 53 and the self-power generation section 542 are provided outside the casing 55 via a lead wire extending from the casing 55.

As shown in the upper part of FIG. 7, the temperature detection section 53 is arranged below the top section 62. The arrangement position of the temperature detection unit 53 is not limited as long as it is a position where the temperature of the product display space, which is the space to be refrigerated or frozen in the showcase 6, can be measured. Note that the drawing lines are not shown in the upper part of FIG. 7 .

The self-power generation section 542 is arranged near the cold air discharge port 64 and the defrosting heater 65 on the lower surface of the top section 62 . The self-power generation unit 542 is arranged so that one surface including the first electrode 543 faces the opening of the defrosting heater 65 and the other surface including the second electrode 544 faces the cold air outlet 64 in the showcase 6. has been done. As a result, a temperature difference occurs between the first electrode 543 and the second electrode 544 during the defrosting operation of the showcase 6. The electromotive force generated due to the temperature difference is supplied to the charging section 541 via the lead wire.

The self-power generation section 542 is not limited to an example using a thermoelectric conversion element such as a Peltier element. The self-power generation unit 542 includes, for example, a photoelectric conversion element that generates power using light from the showcase 6 or a lighting device placed in the facility, and an electromagnetic induction device that generates an induced current by receiving wireless radio waves from a communication network. It may be the used power receiving device.

The power supply section 54 including the self-power generation section 542 of the temperature sensor 5 is connected to the power supply section 63 as described above, and receives power supply from a commercial power source. Here, the facility where the showcase 6 is installed has a first outlet to which power is continuously supplied for 24 hours, and a second outlet to which the power is turned off at a predetermined time and the supply of power is stopped for a predetermined time. is provided. The showcase 6 is energized for 24 hours by being connected to the first outlet. The power supply section 63 to which the temperature sensor 5 is connected corresponds to the second outlet. That is, the power supply section 54 of the temperature sensor 5 is connected to the second outlet side.

The temperature sensor 5 causes the self-power generation unit 542 to generate power according to the defrosting operation of the showcase 6, and charges the charging unit 541. For example, while the power supply is stopped by turning off the second outlet after business hours, the temperature sensor 5 supplies the power stored in the charging unit 541 to each functional element.

As described above, since the temperature sensor 5 has a self-power generation function, the temperature sensor can be placed without considering the position of the first outlet in the facility. Temperature sensors can be installed without depending on the wiring environment, increasing the degree of freedom in system installation.

Note that the power supply section 54 is not limited to the one that includes the charging section 541 and the self-power generation section 542. The power supply section 54 may be configured to supply only electric power obtained from a commercial power source without having a self-power generation function. In that case, the temperature sensor 5 may be connected to the above-mentioned first outlet side.

As mentioned above, the user terminal 3 and the provider terminal 4 are each a personal computer, a smartphone, a tablet terminal, etc., and although detailed illustrations are omitted, in addition to a control section such as a CPU, a storage section, a communication section, for example, a liquid crystal display. It includes a display unit that is a display device such as a display or an organic EL (electroluminescence) display, and an operation unit such as a keyboard or a touch panel device with a built-in display. The user terminal 3 and the provider terminal 4 receive the warning information transmitted from the management device 1 and display it on the display unit.

In the information processing system 100 configured as described above, abnormality detection is performed based on temperature data of the showcase 6. In the information processing system 100, temperature abnormality is detected in consideration of the defrosting operation of the showcase 6.

FIG. 8 is an explanatory diagram illustrating a method of determining the operating state of the showcase 6. The graph shown in FIG. 8 shows the transition of temperature data inside the showcase 6 measured by the temperature sensor 5. The horizontal axis of the graph is the measurement time, and the vertical axis is the temperature.

The showcase 6 operates by appropriately switching between two operating modes: normal operation and defrosting operation. The showcase 6 normally performs a normal operation, and switches to a defrosting operation at an appropriate timing in order to remove frost that has adhered to the inside of the refrigerator when the normal operation continues. When a predetermined period of time has elapsed, the defrosting operation is ended and normal operation is performed again. In the graph of FIG. 8, normal operation is shown before time t1 and after time t4, and defrosting operation is shown between time t1 and time t4.

The temperature inside the showcase 6 during normal operation is maintained within the controlled temperature range, that is, between the upper limit temperature and the lower limit temperature. More specifically, the temperature during normal operation is maintained between the caution temperature, which is lower than the upper limit temperature, and the lower limit temperature. Further, the temperature during the defrosting operation is set higher than the caution temperature, for example, near the upper limit temperature. However, even during the defrosting operation, the temperature inside the showcase 6 is set to a temperature lower than the warning temperature.

The above-mentioned upper limit temperature and warning temperature values correspond to threshold values used in the determination process described later. When using the temperature management service, the user can set a desired upper limit temperature and warning temperature for each showcase 6. Note that the upper limit temperature and warning temperature can be changed at any time after starting to use the service.

In the conventional temperature management method, when the temperature inside the showcase 6 deviates from the controlled temperature range, it is determined that the temperature is abnormal. However, as described above, during the defrosting operation, the temperature inside the showcase 6 may exceed the upper limit temperature. The management device 1 determines that the temperature increase due to the defrosting operation is not abnormal and does not warrant output of a warning. Hereinafter, a specific example will be described using FIG. 8.

Upon acquiring the temperature data from the temperature sensor 5, the management device 1 determines whether the temperature data is equal to or higher than the upper limit temperature. When the temperature data is less than the upper limit temperature, it is determined that the showcase 6 is normal. On the other hand, if the temperature data is equal to or higher than the upper limit temperature, it is determined that there is a possibility that the showcase 6 is abnormal, and it is then determined whether a defrosting operation is to be performed.

When the temperature data is higher than the upper limit temperature and the defrosting operation is being performed, it is determined that the showcase 6 is not abnormal and does not output a warning. Further, when the temperature data is equal to or higher than the upper limit temperature, if the defrosting operation is not performed, it is determined that the showcase 6 is abnormal and a warning should be output.

A method for determining the presence or absence of defrosting operation will be explained. The management device 1 of this embodiment determines whether or not a defrosting operation is to be performed by determining whether the predicted temperature predicted using time-series temperature data exceeds the warning temperature. In the graph of FIG. 8, curves F1 and F2 indicated by broken lines indicate changes in predicted temperature.

As shown by the curve F1, when the predicted temperature is predicted to exceed the warning temperature, it is determined that the defrosting operation is not performed. On the other hand, as shown by curve F2, if it is predicted that the predicted temperature will not exceed the warning temperature, further determination is made.

As a method for calculating the predicted temperature, a known time-series data trend analysis method, regression analysis method, or the like can be used. The management device 1 of this embodiment estimates the predicted temperature using time series data for a predetermined number of times after the temperature data exceeds the upper limit temperature. Specifically, after it is determined that the temperature data exceeds the upper limit temperature at time t2, the temperature data behavior for the period after time t3 is determined based on time-series temperature data measured from time t2 to time t3. Predict. The period for calculating the predicted temperature (prediction period) may be set as appropriate.

Note that calculation of the predicted temperature is not limited to using time-series temperature data after the temperature data exceeds the upper limit temperature. The predicted temperature is a time series of temperature data for a predetermined period before exceeding the upper limit temperature, instead of or in addition to the time series of temperature data after exceeding the upper limit temperature. It may be calculated using temperature data.

When the predicted temperature is predicted not to exceed the warning temperature, a further determination is made as to whether the temperature data has returned to the control temperature range, that is, whether it has fallen below the upper limit temperature. If the temperature data exceeds the upper limit temperature and then falls below the upper limit temperature, it is determined that the defrosting operation is being performed. If the temperature data exceeds the upper limit temperature but does not fall below the upper limit temperature, it is determined that there is no defrosting operation but an abnormality in the showcase 6.

Although it is preferable to determine whether or not the temperature has fallen below the upper limit temperature using the actual value of temperature data measured after time t2 and before time t3, predicted temperature may be used. When using predicted temperatures, data may be limited to data for a relatively short prediction period.

In determining whether the temperature has fallen below the upper limit temperature, the allowable time until the temperature returns to the controlled temperature range may be taken into consideration. For example, if the predicted temperature is predicted not to exceed the warning temperature, monitoring of the temperature data is continued, and the actual value of the temperature data is determined within a preset allowable time from the time when the upper limit temperature is exceeded (for example, time t2). Determine whether the temperature is below the upper limit temperature. If the actual value of the temperature data falls below the upper limit temperature within the allowable time, it is determined that the defrosting operation is being performed. If the actual value of the temperature data does not fall below the upper limit temperature within the allowable time, it is determined that there is no defrosting operation but an abnormality in the showcase 6.

The management device 1 executes the above-described determination process in real time based on the temperature data acquired at predetermined measurement intervals, and performs the temperature management process in the showcase 6. In addition, in this specification, exceeding a specific temperature may mean the said temperature or more, and may also mean exceeding a temperature. Similarly, below a certain temperature may mean below that temperature, or below a certain temperature.

When the temperature inside the showcase 6 exceeds the upper limit temperature and it is determined that the showcase 6 is not being defrosted, the management device 1 transmits warning information to the user terminal 3. The warning information includes, for example, a message notifying a temperature abnormality, information for generating an alert sound, and the like. Note that the destination of the warning information is not limited to the user terminal 3 but may be the provider terminal 4. The warning information may be notified by a display device or a sound generating device of the showcase 6 via the user terminal 3 or the control device 2.

If the temperature inside the showcase 6 exceeds the upper limit temperature and it is determined that the showcase 6 is to be defrosted, the management device 1 does not transmit the warning information. In this way, even if the temperature of the showcase 6 deviates from the controlled temperature range, the management device 1 does not uniformly issue a warning as an abnormality, but appropriately determines whether the showcase 6 is normal or abnormal by taking the defrosting operation into consideration. can be determined.

FIG. 9 is a flowchart illustrating an example of a procedure for outputting warning information. The processes in each of the flowcharts below may be executed by the control unit 11 according to the program 1P stored in the storage unit 12 of the management device 1, or may be executed by a dedicated hardware circuit (for example, FPGA or ASIC) provided in the control unit 11. may be realized, or may be realized by a combination thereof. For example, the management device 1 executes the following process at the timing when new temperature data is transmitted from the control device 2.

The control unit 11 of the management device 1 receives temperature data detected by the temperature sensor 5 from the control device 2 (step S11). When the control unit 21 of the control device 2 receives temperature data from the temperature sensor 5, the control unit 21 associates the received temperature data with the temperature sensor information of the temperature sensor 5 and the measurement date and time, and transmits the data to the management device 1, for example. The control unit 11 associates the received temperature data, temperature sensor information, and measurement date and time and stores them in the temperature DB 122 (step S12).

The control unit 11 reads the upper limit temperature and warning temperature associated with the temperature sensor 5 with reference to the management DB 121, and determines the magnitude relationship between the acquired temperature data and the upper limit temperature, so that the acquired temperature data is determined to be the upper limit temperature. It is determined whether or not it exceeds (step S13). Note that the control unit 11 may further determine whether the temperature data is below the lower limit temperature in step S13. That is, the control unit 11 may determine whether the acquired temperature data is within the control temperature range.

If it is determined that the acquired temperature data does not exceed the upper limit temperature (step S13: NO), the control unit 11 skips the determination process regarding the defrosting operation and advances the process to step S15.

If it is determined that the acquired temperature data exceeds the upper limit temperature (step S13: YES), the control unit 11 executes a determination process to determine whether or not the showcase 6 is being defrosted (step S14).

FIG. 10 is a flowchart illustrating an example of a detailed procedure of a determination process for determining whether or not a defrosting operation is being performed. The processing procedure shown in the flowchart of FIG. 10 corresponds to the details of step S14 in the flowchart of FIG.

The control unit 11 continuously acquires temperature data over a predetermined period from the time when it is determined that the temperature data exceeds the upper limit temperature, and thereby obtains the temperature in a time series for a predetermined number of times after the time when it is determined that the temperature data exceeds the upper limit temperature. Data is acquired (step S21).

The control unit 11 predicts the transition of temperature data after a predetermined period of time by extrapolating the temperature data after a predetermined period of time using a regression analysis method, for example, based on the acquired time-series temperature data. (Step S22).

The control unit 11 determines whether the obtained predicted temperature is predicted to exceed the warning temperature by determining the magnitude relationship between the obtained predicted temperature and the warning temperature (step S23). If it is determined that the predicted temperature is not predicted to exceed the warning temperature, that is, it is determined that the predicted temperature is not predicted to exceed the warning temperature (step S23: NO), the control unit 11 compares the time series temperature data with the upper limit temperature. By determining the magnitude relationship, it is determined whether the time-series temperature data has fallen below the upper limit temperature (step S24).

If it is determined that the time-series temperature data has fallen below the upper limit temperature (step S24: YES), the control unit 11 determines that the showcase 6 is in defrosting operation (step S25), and proceeds to step S15 in the flowchart of FIG. Return processing.

If it is determined that the predicted temperature is predicted to exceed the warning temperature (step S23: YES), or if it is determined that the time-series temperature data is not below the upper limit temperature (step S24: NO), the control unit 11 It is determined that the showcase 6 is not in defrosting operation (step S26). The control unit 11 returns the process to step S15 in the flowchart of FIG.

In the above-described process, if the control unit 11 determines that the time-series temperature data is not below the upper limit temperature, the control unit 11 acquires the temperature data and performs the determination process in step S24 until a preset allowable time elapses. may be executed repeatedly.

Returning to FIG. 9, the explanation will be continued. The control unit 11 determines whether or not to transmit warning information based on a series of determination results (step S15). If it is determined in step S13 that the upper limit temperature is exceeded, and it is determined in step S14 that the defrosting operation is to be performed, the temperature data exceeds the upper limit temperature, and it is determined that the defrosting operation is being performed in showcase 6. corresponds to If the temperature data exceeds the upper limit temperature and it is determined that the showcase 6 is being defrosted, the control unit 11 determines that the showcase 6 is normal and does not transmit warning information. Further, even when it is determined in step S13 that the temperature data does not exceed the upper limit temperature, the control unit 11 determines that the showcase 6 is normal and does not transmit warning information.

If it is determined that the warning information is not to be transmitted (step S15: NO), the control unit 11 ends the exemplary process without transmitting the warning information.

On the other hand, if it is determined in step S13 that the upper limit temperature is exceeded, and it is determined that the defrosting operation is not performed in step S14, if the temperature data exceeds the upper limit temperature and it is determined that the showcase 6 is not in the defrosting operation. corresponds to If the temperature data exceeds the upper limit temperature and it is determined that the showcase 6 is not being defrosted, the control unit 11 determines that the showcase 6 is abnormal and should transmit warning information.

If it is determined that the warning information is to be transmitted (step S15: YES), the control unit 11 generates warning information and transmits the generated warning information to, for example, the user terminal 3 (step S16). The warning information includes a message notifying a temperature abnormality, information for generating an alert sound, and the like. In step S16, the control unit 11 may specify the user terminal 3 associated with the temperature sensor 5 that measured the temperature data based on the information stored in the management DB 121, and may transmit warning information to the specified user terminal 3. The control unit 11 ends the example process.

In the above process, the control unit 11 may set different determination thresholds for the determination process in step S13 and the determination process in step S24. For example, in step S13, the control unit 11 determines whether the temperature data exceeds the first upper limit temperature. Further, the control unit 11 determines whether the temperature data has fallen below the second upper limit temperature in step S24. As an example, the second upper limit temperature is the upper limit temperature of the above-mentioned control temperature zone, and the first upper limit temperature may be a temperature lower than the second upper limit temperature. The first upper limit temperature may be, for example, the above-mentioned caution temperature.

According to this embodiment, temperature abnormality can be detected in consideration of the defrosting operation of the showcase 6, and the necessity of outputting warning information can be changed as appropriate. User convenience is improved by preventing unnecessary warnings from occurring frequently when the temperature rises due to the defrosting operation, and by appropriately issuing a warning only when there is an abnormality in the showcase 6.

The presence or absence of the defrosting operation of the showcase 6 is efficiently and accurately identified by a warning temperature, which is a threshold value provided separately from the upper limit temperature, which is a normal determination threshold value, and by predicting the behavior of the temperature data.

(Second embodiment)
In the second embodiment, a configuration will be described in which the operating state of the showcase 6 is determined using a learning model. In the following, differences from the first embodiment will be mainly explained, and components common to the first embodiment will be denoted by the same reference numerals and detailed explanation thereof will be omitted.

The management device 1 of the second embodiment stores a learning model 123 in the storage unit 12 as shown in FIG. The learning model 123 is a machine learning model that has already learned predetermined training data. The learning model 123 is assumed to be used as a program module that forms part of artificial intelligence software.

FIG. 11 is an explanatory diagram showing an overview of the learning model 123 of the second embodiment. The learning model 123 is a model that outputs information regarding the presence or absence of defrosting operation of the showcase 6 when time-series temperature data inside the showcase 6 is input. In this embodiment, as an example, it is assumed that the learning model 123 outputs information indicating the presence or absence of a defrosting operation. The learning model 123 is a model constructed by a deep learning method using a neural network, for example, and is an RNN (Recurrent Neural Network).

The learning model 123 includes an input layer that inputs time-series temperature data, an output layer that outputs information indicating the presence or absence of a defrosting operation, and an intermediate layer (hidden layer) that extracts feature amounts. The intermediate layer has a plurality of nodes that extract feature amounts of input data, and passes the extracted feature amounts using various parameters to the output layer. When time-series temperature data is input to the input layer, calculations are performed in the intermediate layer using learned parameters, and output information regarding the presence or absence of defrosting operation is output from the output layer.

The time-series temperature data input to the input layer of the learning model 123 includes time-series temperature data over a predetermined period acquired up to the determination time point. The time-series temperature data may be, for example, a plurality of temperature data from the time when the upper limit temperature is exceeded to the determination time. The time-series temperature data may further include temperature data for a predetermined period before exceeding the upper limit temperature. The control unit 11 may input the graphed temperature data stored in time series as an image.

The learning model 123 may further include showcase information as an input element, as shown in FIG. The showcase information is information regarding the showcase 6, and includes, for example, the product name and type of the showcase 6.

The output layer of the learning model 123 outputs an estimation result as to whether or not it is a defrosting operation for time-series temperature data that is input data. Whether or not it is a defrosting operation corresponds to the estimation result for the last temperature data in the time series. The output layer of the learning model 123 includes a plurality of nodes each corresponding to "defrosting operation" or "not defrosting operation" as the estimation result, and outputs the accuracy for each estimation result as a score. The management device 1 can set the estimation result with the highest score or the estimation result with a score greater than or equal to the threshold value as the output value of the output layer. Note that the output layer may have one output node that outputs the most accurate estimation result instead of having a plurality of output nodes that output the accuracy of each estimation result.

Note that the information regarding the presence or absence of the defrosting operation outputted from the output layer is not limited to the presence or absence of the defrosting operation. The learning model 123 may output, for example, a graph showing the transition of temperature data or the transition of temperature data in the case of a defrosting operation. In this case, the management device 1 may determine whether or not the defrosting operation is being performed based on a comparison between the transition of the output temperature data and the actual measured value of the temperature data. The management device 1 determines that defrosting operation is to be performed if the deviation between the output temperature data transition and the actual measured value of temperature data is less than a predetermined value, and if the deviation is greater than or equal to the predetermined value, defrosting operation is to be performed. It can be determined that this is not the case.

The output layer may be constructed to further classify the anomaly content in case the showcase 6 is not in defrost operation. For example, an abnormality in the showcase 6 is classified into a first abnormality related to the temperature inside the showcase 6 and a second abnormality related to the temperature sensor 5. The first abnormality is an abnormality caused by the showcase 6, such as, for example, the temperature inside the showcase 6 itself being high. The second abnormality is an abnormality caused by the temperature sensor 5, such as temperature data not being acquired correctly. The output layer outputs output information including such anomaly classification. Specifically, the output layer includes multiple cases where the showcase 6 is in defrosting operation and is normal, the showcase 6 is not in defrosting operation and is in the first abnormality, and the showcase 6 is not in defrosting operation and is in the second abnormality. Output the classification results of class classification.

Note that the learning model 123 may be generated for each type of showcase 6. By generating the learning model 123 for each type of showcase 6, the operating status of each showcase 6 can be more suitably reflected in the learning model 123.

The management device 1 collects in advance, as training data, an information group in which the presence or absence of a known defrosting operation according to the operating state of the showcases 6 is added to the actual measured values of temperature data in time series for various showcases 6. Then, the learning model 123 is learned. The management device 1 learns various parameters constituting the learning model 123 using, for example, an error backpropagation method so as to output an estimation result of the presence or absence of a defrosting operation according to time-series temperature data. The parameter is, for example, a weight (coupling coefficient) between neurons. When the learning is completed, a learning model 123 is constructed that is trained to appropriately recognize the presence or absence of a defrosting operation with respect to time-series temperature data. Note that the learning model 123 may be constructed by an external device, and the learning model 123 transmitted from the external device may be stored in the storage unit 12 of the management device 1.

The configuration of the learning model 123 is not limited to the above example. The learning model 123 only needs to be able to identify information regarding the presence or absence of a defrosting operation from time-series temperature data. The learning model 123 may be a model based on other learning algorithms such as CNN (Convolution Neural Network), LSTM (Long Short-Term Memory), Transformer, support vector machine, decision tree, etc.

When the management device 1 of the second embodiment executes the same process as shown in FIG. 9 of the first embodiment, in step S14, the management device 1 uses the above-described learning model 123 to determine whether or not it is a defrosting operation of the showcase 6. Execute the determination process to determine.

FIG. 12 is a flowchart illustrating an example of a detailed procedure of a determination process for determining whether or not a defrosting operation is being performed. The processing procedure shown in the flowchart of FIG. 12 corresponds to the details of step S14 in the flowchart of FIG.

Based on the information stored in the temperature DB 122, the control unit 11 of the management device 1 acquires time-series temperature data over a predetermined period acquired up to the time when it is determined that the temperature data exceeds the upper limit temperature (step S31).

The control unit 11 inputs the acquired time-series temperature data over a predetermined period to the learning model 123 (step S32). When a plurality of learning models 123 are stored for each type of showcase 6, the control unit 11 refers to the management DB 121 to specify the type of showcase 6 corresponding to the temperature data, and It is preferable to select a learning model 123 that corresponds to the type of . The control unit 11 executes the determination process using the selected learning model 123.

The control unit 11 acquires the identification result output from the learning model 123 as to whether or not it is a defrosting operation (step S33). Note that the control unit 11 may determine whether or not it is a defrosting operation by executing predetermined post-processing based on the output information output from the learning model 123.

Note that the management device 1 may re-learn the learning model 123 by acquiring data on the actual operating status of the showcase 6. For example, the management device 1 obtains, through the control device 2, time-series temperature data and the actual operating status of the showcase 6 corresponding to the time-series temperature data in association with each other. The management device 1 creates training data that associates the acquired time-series temperature data with the presence or absence of a new defrost operation (corrected data) in response to the identification result of whether or not the defrost operation is the output of the learning model 123. Then, the learning model 123 is retrained using the training data. By performing relearning, the accuracy of the learning model 123 can be further improved through system operation.

According to the present embodiment, by using the learning model 123 to analyze the conditions of refrigerated/frozen showcases manufactured by various manufacturers and the facilities where the showcases are used, it is easier to determine whether or not the defrosting operation is being performed. Moreover, it can be determined with high accuracy.

(Third embodiment)
In the third embodiment, a configuration for changing the measurement interval in the temperature sensor 5 will be described. In the following, differences from the first embodiment will be mainly explained, and components common to the first embodiment will be denoted by the same reference numerals and detailed explanation thereof will be omitted.

The temperature sensor 5 of the third embodiment is configured to be able to measure temperature by switching between a plurality of measurement intervals. The temperature sensor 5 of the third embodiment normally measures the temperature at the first measurement interval, and when the temperature data in the showcase 6 exceeds the upper limit temperature, the temperature sensor 5 measures the temperature at a second measurement interval shorter than the first measurement interval. to measure the temperature.

FIG. 13 is a flowchart illustrating an example of a measurement interval change processing procedure in the third embodiment. The control device 2 of the third embodiment executes the process shown in FIG. 13 when temperature data is acquired from the temperature sensor 5 when the measurement interval of the temperature sensor 5 is the first measurement interval.

The control unit 21 of the control device 2 determines whether the current temperature data exceeds the upper limit temperature by determining the magnitude relationship between the current temperature data and the upper limit temperature (step S41). If it is determined that the current temperature data does not exceed the upper limit temperature (step S41: NO), the control unit 21 ends the process. The control unit 21 may execute a loop process that returns the process to step S41.

If it is determined that the current temperature data exceeds the upper limit temperature (step S41: YES), the control unit 21 outputs a measurement instruction to set the measurement interval to the second measurement interval to the temperature sensor 5 (step S42). The temperature sensor 5 receives the measurement instruction and thereafter measures temperature data at the second measurement interval.

The control unit 21 continues monitoring the temperature data and determines whether the new temperature data acquired after outputting the measurement instruction has fallen below the upper limit temperature, that is, whether the temperature has returned to the control temperature range (step S43). . If it is determined that the new temperature data is not below the upper limit temperature (step S43: NO), the control unit 21 returns the process to step S43 and waits until the new temperature data becomes below the upper limit temperature.

If it is determined that the new temperature data is lower than the upper limit temperature (step S43: YES), the control unit 21 outputs a measurement instruction that sets the measurement interval to the first measurement interval to the temperature sensor 5 (step S44). The temperature sensor 5 receives the measurement instruction and thereafter measures temperature data at the first measurement interval. The control unit 21 may execute a loop process that returns the process to step S41.

According to the above configuration, for example, in the temperature transition graph illustrated in FIG. 8, at time t2 when the temperature data exceeds the upper limit temperature, the measurement interval is switched from the first measurement interval to the second measurement interval, and the temperature data is changed to the upper limit temperature. At time t5 when the temperature drops below the temperature, the measurement interval is switched again from the second measurement interval to the first measurement interval. By measuring temperature data at short second measurement intervals, it is possible to understand temperature changes in more detail than in normal times.

Note that although an example has been described above in which the control device 2 determines the measurement interval and outputs the measurement instruction, the processing subject is not limited, and part or all of the processing in FIG. 13 may be executed by the management device 1, for example. It's okay.

Furthermore, in the above configuration, the management device 1 may determine whether or not a defrosting operation is to be performed or whether or not it is necessary to output warning information based on the measurement interval of temperature data. For example, after the measurement interval is switched from the first measurement interval to the second measurement interval due to temperature data exceeding the upper limit temperature, the management device 1 changes the measurement interval to the first measurement interval within a preset allowable time. Determine whether or not it can be switched to. If it is determined that the measurement interval has not been switched back to the first measurement interval within the allowable time, the management device 1 determines that the defrosting operation is not being performed. If it is determined that the measurement interval has been switched to the first measurement interval within the allowable time, the management device 1 determines that the defrosting operation is being performed. The management device 1 may execute the determination process using the above-mentioned measurement interval instead of the determination process described in step S24 of FIG. 10.

According to this embodiment, the measurement interval of temperature data is changed as appropriate depending on the temperature data in the showcase 6. When the temperature inside the showcase 6 rises, temperature changes can be appropriately grasped by measuring temperature data at short measurement intervals. It becomes easy to estimate the presence or absence of defrosting operation, and it becomes possible to detect the possibility of an abnormality at an early stage and promptly output a warning.

(Fourth embodiment)
In the fourth embodiment, a configuration will be described in which warning information is output depending on the abnormality content of the showcase 6. In the following, differences from the first embodiment will be mainly explained, and components common to the first embodiment will be denoted by the same reference numerals and detailed explanation thereof will be omitted.

When the management device 1 of the fourth embodiment determines to output warning information, it classifies the contents of the abnormality and changes the terminal device to which the warning information is output according to the contents of the abnormality. As described above, for example, an abnormality in the showcase 6 is classified into a first abnormality related to the temperature inside the showcase 6 and a second abnormality related to the temperature sensor 5.

The first abnormality is an abnormality caused by the showcase 6. In the case of such a first abnormality, there is a high possibility that the showcase 6 itself needs to be repaired, replaced, or the like. Therefore, in the case of the first abnormality, the abnormality is notified to the user terminal 3 of the user who manages the showcase 6 as a terminal device associated with the showcase 6. The user receives the warning information through the user terminal 3 and can take measures such as contacting the manufacturer of the showcase 6.

The second abnormality is an abnormality caused by the temperature sensor 5. In the case of such a second abnormality, it is necessary to replace the battery of the temperature sensor 5, restart the temperature sensor 5 or the control device 2 to resolve the communication abnormality of the temperature sensor 5, repair or replace the temperature sensor 5, etc. There is a high possibility that this is an abnormality that should be addressed by the service provider first. Therefore, in the case of the second abnormality, the abnormality is notified to the provider terminal 4 of the service provider as the terminal device associated with the showcase 6. The service provider receives the warning information through the provider terminal 4 and can take measures such as restarting the device or arranging the temperature sensor 5. Alternatively, the service provider may present to the user how to deal with the problem, such as replacing the battery of the temperature sensor 5.

FIG. 14 is a flowchart illustrating an example of a processing procedure executed by the information processing system 100 of the fourth embodiment. The process in the flowchart of FIG. 14 may be executed, for example, after it is determined in step S15 of the flowchart of FIG. 9 that warning information is to be transmitted.

The control unit 11 of the management device 1 determines whether a first abnormality has occurred (step S51). As an example, when the controller 11 determines that the showcase 6 is abnormal and temperature data is continuously acquired, it can determine that the first abnormality has occurred. Further, when the control unit 11 determines that the showcase 6 is abnormal, for example, and temperature data is not continuously acquired, the control unit 11 can determine that the first abnormality has not occurred.

If it is determined that the first abnormality has occurred (step S51: YES), the control unit 11 generates warning information indicating that the temperature inside the showcase 6 is abnormal, and sends the generated warning information to the user terminal 3. Transmit (step S52). The warning information further includes information for identifying the temperature sensor 5 or showcase 6 that has detected the abnormality. In step S52, the control unit 11 may specify the user terminal 3 associated with the temperature sensor 5 that measured the temperature data based on the information stored in the management DB 121, and may transmit warning information to the specified user terminal 3.

The user terminal 3 receives the warning information from the management device 1 (step S53), displays the warning information through the display unit, and ends the process.

On the other hand, if it is determined that the first abnormality has not occurred, that is, the second abnormality has occurred (step S51: NO), the control unit 11 generates warning information indicating that the temperature sensor 5 is abnormal, The generated warning information is transmitted to the provider terminal 4 (step S54). In step S54, the control unit 11 may specify the provider terminal 4 associated with the temperature sensor 5 that measured the temperature data based on the information stored in the management DB 121, and may transmit warning information to the specified provider terminal 4. .

The provider terminal 4 receives the warning information from the management device 1 (step S55), and displays the warning information through the display unit, for example. The provider terminal 4 may create a notification indicating a further response method on the user side in accordance with the received warning information, and may send the generated notification to the user terminal 3.

According to this embodiment, it is possible to appropriately present warning information to a target person who should respond to an abnormality. The user side can easily determine whether or not there is an abnormality that the user should take care of himself or not, which improves convenience.

(Fifth embodiment)
In the fifth embodiment, a configuration in which the temperature sensor 5 includes a plurality of temperature detection sections 53 will be described. In the following, differences from the first embodiment will be mainly explained, and components common to the first embodiment will be denoted by the same reference numerals and detailed explanation thereof will be omitted.

FIG. 15 is a block diagram showing a configuration example of the temperature sensor 5 of the fifth embodiment. The temperature sensor 5 includes two temperature detection sections, a first temperature detection section 53a and a second temperature detection section 53b. The first temperature detection section 53a and the second temperature detection section 53b are, for example, thermistors. As conceptually shown in FIG. 15, the first temperature detection section 53a is provided outside the casing 55 via a lead wire from the casing 55, and the second temperature detection section 53b is provided inside the casing 55. It is being The first temperature detection section 53a functions for temperature detection, and the second temperature detection section 53b functions for temperature correction. The control unit 51 of the temperature sensor 5 can obtain measured values in each of the first temperature detection unit 53a and the second temperature detection unit 53b by appropriately switching a switching unit such as a switch.

The first temperature detection section 53a and the second temperature detection section 53b are calibrated at the time of shipment so that their resistance values are equal. The storage unit 12 of the management device 1 stores predetermined approximate expressions indicating the temperature characteristics of the first temperature detection unit 53a and the second temperature detection unit 53b, and constants included in the approximation expressions according to time-measured changes in the temperature characteristics. A correction table for correction is stored in advance.

The temperature sensor 5 transmits temperature data measured by the first temperature detection section 53a and the second temperature detection section 53b at substantially the same time to the management device 1 via the control device. The management device 1 calibrates the temperature data of the first temperature detection section 53a based on the comparison of the measured values of the first temperature detection section 53a and the second temperature detection section 53b.

FIG. 16 is a flowchart illustrating an example of a temperature data correction processing procedure.
The control unit 11 of the management device 1 transmits the first temperature data detected by the first temperature detection unit 53a of the temperature sensor 5 and the second temperature data detected by the second temperature detection unit 53b to the control device. 2 (step S61).

The control unit 11 calculates the difference (absolute value of the difference) between the first temperature data and the second temperature data, and determines whether the calculated difference in the temperature data is equal to or greater than a preset threshold value. (Step S62). If it is determined that the difference in temperature data is less than the preset threshold (step S62: NO), the control unit 11 ends the process.

If it is determined that the difference in temperature data is equal to or greater than a preset threshold (step S62: YES), the control unit 11 corrects the constant of the approximation formula based on the correction table stored in the storage unit 12. The temperature data of No. 1 is corrected (step S63). The control unit 11 ends the process.

According to this embodiment, by providing the second temperature detection section 53b for temperature correction, it is possible to detect a failure or a decrease in detection accuracy of the first temperature detection section 53a at an early stage. Furthermore, since the first temperature data can be corrected based on the second temperature data, the frequency of sensor replacement can be reduced, leading to cost reduction.

The processing entity of each of the above-described flowcharts is not limited. For example, part or all of the processing executed by the management device 1 may be executed by the user terminal 3, or may be executed by the control device 2.

The embodiments disclosed herein are illustrative in all respects and should not be considered restrictive. The technical features described in each example can be combined with each other, and the scope of the present invention is intended to include all changes within the scope of the claims and the range of equivalents to the scope of the claims. be done.
The sequences shown in each embodiment are not limited, and each processing procedure may be executed with the order changed, or a plurality of processes may be executed in parallel, as long as there is no contradiction. The processing entity of each process is not limited, and the processes of each device may be executed by other devices as long as there is no contradiction.

Items described in each embodiment can be combined with each other. Moreover, the independent claims and dependent claims recited in the claims may be combined with each other in any and all combinations, regardless of the form in which they are cited. Further, although the scope of claims uses a format in which claims refer to two or more other claims (multi-claim format), the invention is not limited to this format. It may be written using a multi-claim format that cites at least one multi-claim.

100 Information processing system 1 Management device (information processing device)
11 Control unit 12 Storage unit 123 Learning model 1P Program 1A Recording medium 13 Communication unit 2 Control device 21 Control unit 22 Storage unit 23 First communication unit 24 Second communication unit 3 User terminal (terminal device)
4 Provider terminal (terminal device)
5 Temperature sensor 51 Control section 52 Communication section 53 Temperature detection section 53a First temperature detection section 53b Second temperature detection section 54 Power supply section 541 Charging section 542 Self-power generation section 543 First electrode 544 Second electrode 545 Joint section 6 Showcase 63 Power supply section 64 Cold air discharge port 65 Defrost heater

Claims (15)

Obtaining temperature data within the showcase measured by a temperature sensor provided in the showcase;
Based on the acquired temperature data, if it is determined that the temperature in the showcase exceeds a first threshold and the showcase is not in a defrosting operation, output a warning;
Based on the acquired temperature data, if the temperature inside the showcase exceeds the first threshold and it is determined that the showcase is being defrosted, a warning is not output. The temperature management method according to claim 1, wherein when the predicted temperature predicted by the temperature data is predicted not to exceed a second threshold higher than the first threshold, it is determined that the showcase is being defrosted. Temperature management according to claim 1 or 2, wherein if the predicted temperature predicted by the temperature data is predicted to exceed a second threshold value higher than the first threshold value, it is determined that the showcase is not being defrosted. Method. When the time-series temperature data in the showcase is input, the obtained time-series temperature data is input to a learning model that outputs information regarding the presence or absence of the defrosting operation of the showcase. The temperature control method according to claim 1 or 2, wherein the temperature control method outputs the following. The temperature sensor measures temperature data at a measurement interval shorter than a measurement interval before exceeding the first threshold when the temperature in the showcase exceeds the first threshold. Temperature control method described. After the temperature in the showcase exceeds the first threshold, if the time-series temperature data after exceeding the first threshold is below the first threshold, it is determined that the showcase is in a defrosting operation. The temperature control method according to claim 1 or claim 2. The temperature according to claim 1 or 2, wherein it is determined based on the temperature data whether a first abnormality related to the temperature in the showcase has occurred or a second abnormality related to the temperature sensor has occurred. Management method. The temperature management method according to claim 7, wherein when it is determined that the first abnormality has occurred, information indicating that the temperature in the showcase is abnormal is output to a terminal device associated with the showcase. The temperature management method according to claim 7, wherein when it is determined that the second abnormality has occurred, information indicating that the temperature sensor is abnormal is output to a terminal device associated with the showcase. The temperature sensor includes a Peltier element including a first electrode and a second electrode,
The temperature control method according to claim 1 or 2, wherein the first electrode is arranged near a cold air outlet in the showcase, and the second electrode is arranged near a defrosting heater of the showcase. . The facility where the showcase is installed is provided with a first outlet to which electricity is continuously supplied for 24 hours and a second outlet to which the supply of electricity is stopped for a predetermined time,
The temperature management method according to claim 1 or 2, wherein the temperature sensor having a self-power generation section is connected to the second outlet side. A first temperature detection section is provided outside the casing of the temperature sensor, and a second temperature detection section is provided inside the casing of the temperature sensor,
The temperature management method according to claim 1 or 2, wherein the temperature data obtained from the first temperature detection section is corrected based on the temperature data obtained from the second temperature detection section. Equipped with an information processing device and a temperature sensor,
The information processing device includes:
Obtaining temperature data within the showcase measured by the temperature sensor provided in the showcase;
Based on the acquired temperature data, if it is determined that the temperature in the showcase exceeds a first threshold and the showcase is not in a defrosting operation, output a warning;
If it is determined that the temperature in the showcase exceeds the first threshold value based on the acquired temperature data and it is determined that the showcase is in a defrosting operation, a control unit that executes a process that does not output a warning is provided. Information processing system. Obtaining temperature data within the showcase measured by a temperature sensor provided in the showcase;
Based on the acquired temperature data, if it is determined that the temperature in the showcase exceeds a first threshold and the showcase is not in a defrosting operation, output a warning;
A program for causing a computer to execute a process that does not output a warning when the temperature inside the showcase exceeds the first threshold and it is determined that the showcase is in a defrosting operation based on the acquired temperature data. . Obtaining temperature data within the showcase measured by a temperature sensor provided in the showcase;
Based on the acquired temperature data, if it is determined that the temperature in the showcase exceeds a first threshold and the showcase is not in a defrosting operation, output a warning;
If it is determined that the temperature in the showcase exceeds the first threshold value based on the acquired temperature data and it is determined that the showcase is in a defrosting operation, a control unit that executes a process that does not output a warning is provided. Information Processing equipment.

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