JP6350842B1 - Detection device and detection system - Google Patents

Abstract

To provide a detection device and a detection system that can be easily attached to an existing reservoir and can centrally manage the remaining amount of storage stored in the reservoir. A detection device (20) according to the present invention is a detection device attached to a reservoir (30) having an opening (32), and is stored in the reservoir from the opening (40). A detection unit (251) for detecting the detection result, a storage unit (26) for storing the detection result of the detection unit, a transmission unit (28) for transmitting the detection result stored in the storage unit, and a coupling unit coupled to the opening (211). [Selection] Figure 4

Description

  The present invention relates to a detection device and a detection system.

  For example, in cold regions, kerosene that is used as a heating fuel in winter is stored in an outdoor installation type reservoir such as a home tank installed in each household. In general, the remaining amount of kerosene in the reservoir is confirmed by the kerosene consumer (owner of the reservoir). The consumer requests a kerosene dealer (hereinafter referred to as a “trader”) to replenish kerosene when the remaining amount of kerosene in the reservoir is low. In this case, each time a contractor receives a request, he must deal with it individually. For this reason, the contractor is forced to deliver inefficient kerosene, and the delivery cost may be added to the kerosene price. As a result, in suburbs and depopulated areas other than urban areas, there are problems such as a rise in kerosene prices and a decrease in the frequency of kerosene delivery.

  In recent years, in order to solve this problem, the remaining amount of kerosene in each reservoir is centrally managed by measuring the remaining amount of kerosene with a sensor and collecting the measurement results via a communication line. Systems have been proposed (see, for example, Patent Document 1 and Patent Document 2).

  The system disclosed in Patent Literature 1 predicts the date and time when the reservoir is empty from the consumer's kerosene consumption trend, and constructs an efficient supply route according to the remaining amount of kerosene. The system disclosed in Patent Document 2 is based on the amount of data handled by the system by changing the frequency of transmission of measurement results based on kerosene consumption, consumer convenience, and environmental conditions such as season and temperature. Suppress.

JP 2003-298757 A JP 2012-86941 A

  Such a system requires a measuring instrument that measures (detects) the amount of liquid in each reservoir and a communication device that transmits the measurement results of the measuring instrument. In many cases, the measuring instrument is provided in advance in the reservoir. However, most of them are methods in which the consumer reads the scale, not the method of outputting the measurement results to the outside. In addition, even if the storage device includes a measuring instrument that outputs measurement results to the outside, in order to construct the system disclosed in Patent Document 1 or Patent Document 2, the standard of the measuring instrument (measurement method, The unit of output value, resolution, etc.) must be unified. That is, in order to build the system, a new storage device (hereinafter referred to as “detection device”) including a measuring instrument with a unified standard, a communication device, and a power source necessary for these operations is stored. Must be attached to.

  When a detection device is newly attached to the reservoir, processing of the reservoir (drilling, installation of a dedicated fixing member, etc.) is required to fix the detection device to the reservoir. Further, as described above, the reservoir is installed outdoors. For this reason, when the detector is attached to the reservoir, it is necessary to consider the waterproofness of the detector, the incombustibility of combustible materials, and the inundation of the reservoir. Thus, it is not easy to attach the detection device to a reservoir, especially an existing reservoir.

  The present invention has been made to solve the above-described problems of the prior art, and can be easily attached to an existing storage device, and the remaining amount of storage material stored in the storage device can be unified. It is an object of the present invention to provide a detection device and a detection system that can be managed.

  A detection device according to the present invention is a detection device attached to a reservoir having an opening, and is a detection unit that detects a stored item stored in the reservoir from the opening, and a memory that stores a detection result of the detection unit. And a transmission unit that transmits the detection result stored in the storage unit, and a coupling unit that couples to the opening.

  ADVANTAGE OF THE INVENTION According to this invention, while being able to attach a detection apparatus to an existing store easily, the residual amount of the stored item stored in the store can be managed centrally.

It is a functional block diagram which shows embodiment of the detection system concerning this invention. It is a functional block diagram of the server with which the detection system of FIG. 1 is provided. It is a side view which shows embodiment of the detection apparatus concerning this invention. It is a functional block diagram of the detection apparatus of FIG. It is A arrow directional view of the detection apparatus of FIG. FIG. 6 is a cross-sectional view of the detection device of FIG. It is sectional drawing which shows the state in which the detection apparatus of FIG. 3 was attached to the opening part of the store. It is a flowchart which shows operation | movement of the detection apparatus of FIG. It is a schematic diagram which shows the example of the information memorize | stored in the detection result database in the memory | storage part with which the detection apparatus of FIG. 3 is provided. It is a flowchart which shows operation | movement of the server of FIG. It is a schematic diagram which shows the example of the information memorize | stored in the liquid level distance database in the server memory | storage part with which the server of FIG. 2 is provided. It is a schematic diagram which shows the example of the information memorize | stored in the temperature database in the server memory | storage part with which the server of FIG. 2 is provided. It is a schematic diagram which shows the example of the information memorize | stored in the detection information database in the server memory | storage part with which the server of FIG. 2 is provided. It is a schematic diagram which shows the example of the information memorize | stored in the storage database in the server memory | storage part with which the server of FIG. 2 is provided.

  Hereinafter, embodiments of a detection apparatus and a detection system according to the present invention will be described with reference to the drawings.

● Detection system ●
First, a detection system according to the present invention will be described.

Configuration of Detection System FIG. 1 is a functional block diagram showing an embodiment of a detection system according to the present invention.

  The detection system 1 is connected to the reservoir 30 to detect (manage) the storage amount of the storage 40 stored in the reservoir 30. The detection system 1 includes a server 10 and a detection device 20. The reservoir 30 and the stored item 40 will be described later.

Server Configuration FIG. 2 is a functional block diagram of the server 10.
The server 10 receives the detection result of the stored item 40 detected by the detection device 20 from the detection device 20, and generates detection information based on the detection result. The detection result and detection information will be described later. The server 10 is constituted by a personal computer, for example. The server 10 includes a server communication unit 11, a server control unit 12, and a server storage unit 13.

  The server communication unit 11 is a unit that is connected to the detection device 20 via a communication line, receives a detection result from the detection device 20, and transmits control information to the detection device 20. The server communication unit 11 is, for example, a communication interface (I / F) such as a connector or a terminal. The communication line is, for example, a wireless communication line such as LTE (Long Term Evolution), LPWA (Low Power Wide Area), or NB-IoT (Narrow Band Internet of Things).

  “Control information” is information for controlling the operation of the detection device 20. The control information includes, for example, a timing at which the detection device 20 detects the stored item 40 (hereinafter referred to as “detection timing”) and a timing at which the detection device 20 transmits a detection result to the server 10 (hereinafter referred to as “transmission timing”). Etc. The detection timing and transmission timing will be described later.

  The server communication unit 11 is connected to an external device 50 described later, and transmits information (detection information described later) according to a request from the external device 50 to the external device 50. The server communication unit 11 is an example of a server transmission unit in the present invention.

  The server control unit 12 is a means for controlling the operation of the entire server 10 and executing information processing and calculation described later. The server control unit 12 is, for example, a processor such as a CPU (Central Processing Unit), an MPU (Micro Processing Unit), or a DSP (Digital Signal Processor), an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), or the like. It is constituted by an integrated circuit. The operation of the server control unit 12 will be described later.

  The server storage unit 13 is a unit that stores information necessary for the detection system 1 to execute information processing described later. The server storage unit 13 is configured by a recording device such as an HDD (Hard Disk Drive) or an SSD (Solid State Drive). The server storage unit 13 stores a distance database DB11, a temperature database DB12, a detection information database DB13, a reservoir database DB14, each reference value, and the like which will be described later.

● Detection device ●
Next, the detection apparatus according to the present invention will be described.

FIG. 3 is a side view showing an embodiment of the detection device 20. The figure also shows a part of the reservoir 30 (an opening 32 described later).

  The detection device 20 is attached to the reservoir 30 and detects the stored item 40 stored in the reservoir 30. The configuration of the detection device 20 will be described later. The detection device 20 is an example of a detection device according to the present invention.

FIG. 4 is a functional block diagram of the detection device 20.
FIG. 5 is a view of the detection device 20 as viewed in the direction of arrow A in FIG.
6 is a cross-sectional view of the detection device 20 taken along the line BB in FIG. The figure schematically shows the internal structure of the case 21.

  The detection device 20 includes a case 21, a circuit board 22, a power supply management unit 23, a power supply unit 24, a detection unit 25, a storage unit 26, a control unit 27, and a communication unit 28. .

  The case 21 contains a circuit board 22, a power supply management unit 23, a power supply unit 24, a detection unit 25, a storage unit 26, a control unit 27, and a communication unit 28. Protect from. The case 21 is made of, for example, a synthetic resin having flame retardancy such as polyethylene. The case 21 has a so-called bottomed cylindrical shape in which one end is open and the other end is closed to form a ceiling surface. The case 21 includes a coupling portion 211.

  The coupling portion 211 is coupled to an opening 32 (see FIG. 7) of the reservoir 30 described later, and fixes the detection device 20 (case 21) to the reservoir 30. The coupling portion 211 is disposed on the inner peripheral surface of the case 21 adjacent to the opening end of the case 21. The coupling portion 211 is a female screw.

  In addition, what is necessary is just to couple | bond the coupling | bond part in this invention with the opening part of a reservoir | reserver, and is not limited to an internal thread. That is, for example, the coupling portion may be an uneven surface corresponding to the shape of the opening of the reservoir.

  The circuit board 22 is a board on which the power supply management unit 23, the power supply unit 24, the detection unit 25, the storage unit 26, the control unit 27, and the communication unit 28 are mounted. The circuit board 22 has a disk shape, for example. The circuit board 22 includes an inner surface facing the ceiling surface of the case 21 and an outer surface facing the opening end of the case 21 when the circuit board 22 is accommodated in the case 21.

  The power supply management unit 23 is means for managing the supply of power from the power supply unit 24 to the detection unit 25, the storage unit 26, the control unit 27, and the communication unit 28. The power supply management unit 23 includes an RTC 231 (Real Time Clock) and a switch 232. The switch 232 is, for example, an FET (Field Effect Transistor) switch. The management of power supply by the power supply management unit 23 will be described later.

  The power supply unit 24 is a unit that supplies power to the power supply management unit 23, the detection unit 25, the storage unit 26, the control unit 27, and the communication unit 28. The power supply unit 24 is, for example, a lithium ion storage battery. The power feeding unit 24 is mounted on the inner surface of the circuit board 22.

  In addition, the electric power feeding part in this invention may be mounted in the inner surface of a circuit board or a case via elastic materials (not shown), such as sponge. With this configuration, the power supply unit does not come off the circuit board even if the case or the circuit board expands or contracts in accordance with a temperature change of the power supply unit or a temperature change outside the detection device.

  The detection unit 25 is a means for detecting (measuring) a detection target such as the stored item 40 stored in the reservoir 30 and the environment (temperature) outside the reservoir 30. The detection unit 25 includes a first detection unit 251, a second detection unit 252, and a protection member 253 (see FIG. 6).

  The first detector 251 detects the stored item 40 stored in the reservoir 30. The first detector 251 is a laser-type distance sensor that measures the distance from the first detector 251 to the stored item 40. The first detection unit 251 is a detection unit in the present invention. The first detection unit 251 is mounted on the outer surface of the circuit board 22.

  In addition, the 1st detection part in this invention should just be able to measure the distance from a 1st detection part to a stored thing, and is not limited to the distance sensor of a laser system. That is, for example, the first detection unit may be a non-contact distance sensor such as an ultrasonic method or an infrared method, or a contact distance sensor such as a float method.

  The second detector 252 indirectly detects (measures) the temperature outside the reservoir 30 through the space inside the case 21 surrounded by the case 21 and the circuit board 22 and the case 21. . The second detection unit 252 is, for example, a temperature sensor that converts a temperature change such as a thermistor into an electrical signal. The second detection unit 252 is mounted on the inner surface of the circuit board 22.

  The protection member 253 protects the first detection unit 251 from, for example, the vaporized gas of the stored product 40. The protection member 253 is, for example, a synthetic resin such as polyethylene. The protection member 253 is a transparent film. The protection member 253 covers the first detection unit 251 mounted on the outer surface of the circuit board 22.

  The protective member in the present invention may cover the entire outer surface of the circuit board.

  The memory | storage part 26 is a means to memorize | store the information required in order for the detection apparatus 20 to perform the information processing mentioned later. The storage unit 26 includes, for example, a RAM (Random Access Memory), a semiconductor memory element such as a flash memory, and the like. The storage unit 26 stores a detection result database DB21 described later, control information, a reference value, and the like.

  The control unit 27 is means for controlling the operation of the entire detection device 20. The control unit 27 is, for example, a processor such as a central processing unit (CPU), a micro processing unit (MPU), or a digital signal processor (DSP), or an integration such as an application specific integrated circuit (ASIC) or a field programmable gate array (FPGA). Consists of a circuit. The control unit 27 is mounted on the inner surface of the circuit board 22.

  The communication unit 28 is connected to the server communication unit 11 via a communication line, and is a means for transmitting the detection result of the detection unit 25 to the server 10 and receiving control information from the server 10. The communication unit 28 is an example of a transmission unit in the present invention. The communication unit 28 includes a communication module 281 and an antenna 282 (see FIG. 6).

  The communication module 281 is a communication module corresponding to a wireless communication line such as LTE, LPWA, or NB-IoT. The antenna 282 is a film antenna, for example. The communication module 281 and the antenna 282 are mounted on the inner surface of the circuit board 22.

Assembly of the detection device Next, the assembly of the detection device 20 will be described.

  First, the power supply management unit 23, the power supply unit 24, the second detection unit 252, the storage unit 26, the control unit 27, and the communication unit 28 are mounted on the inner surface of the circuit board 22.

  Next, the first detection unit 251 is mounted on the outer surface of the circuit board 22 and covered with the protection member 253.

  Next, the circuit board 22 is accommodated in the case 21. The circuit board 22 is disposed closer to the ceiling surface than the coupling portion 211. The inner surface of the circuit board 22 faces the ceiling surface of the case 21, and the outer surface of the circuit board 22 faces the opening end of the case 21. At this time, for example, a sealing material such as packing is filled between the outer peripheral edge of the circuit board 22 and the inner peripheral surface of the case 21. Therefore, the circuit board 22 is fixed to the inside of the case 21 and the space surrounded by the case 21 and the circuit board 22 is sealed.

FIG. 7 is a cross-sectional view showing a state where the detection device 20 is attached to the opening 32 of the reservoir 30.

  The reservoir 30 stores the stored item 40. The reservoir 30 is a tank that stores liquid supplied from the outside, such as a home tank for kerosene installed outdoors. The reservoir 30 includes a main body 31 and an opening 32.

  The main body 31 stores the stored item 40. The main body 31 is, for example, a hollow rectangular parallelepiped. The main body 31 includes a circular hole on the upper surface.

  The opening 32 is a part of the reservoir 30 that serves as a receptacle when the stored product 40 is supplied to the main body 31. The opening 32 has a flat cylindrical shape with both ends opened. The opening 32 is disposed on the upper surface of the main body 31 with both ends directed in the vertical direction (the vertical direction in the drawing of FIG. 7). The opening 32 surrounds the hole on the upper surface of the main body 31. That is, the space inside the main body 31 communicates with the space outside the main body 31 through the opening 32. The opening 32 includes a coupling portion 321 (see FIG. 3).

  The coupling unit 321 fixes the detection device 20 to the reservoir 30 (opening 32). The coupling portion 321 is disposed on the outer peripheral surface of the opening portion 32. The coupling | bond part 321 is an example of the external thread part in this invention, and is an external thread corresponding to the connection part 211 of the case 21 which is an internal thread.

  In place of the lid (not shown) of the opening 32, the detection device 20 is attached to the opening 32. At this time, the coupling portion 211 that is a female screw is coupled to the coupling portion 321 that is a male screw. The coupling portion 211 of the detection device 20 can be attached to and detached from the opening 32. That is, the shape and standard of the female screw that is the coupling portion 211 of the detection device 20 are the same as the shape and standard of the female screw of the lid of the opening 32. That is, the detection device 20 can be replaced with a lid of the opening 32. In other words, the detection device 20 functions as a lid for the opening 32. As a result, the detection device 20 can be easily attached to the reservoir 30 without drilling the reservoir 30 or installing a dedicated fixing member.

  The store 40 is a liquid such as kerosene or drinking water that is stored in the store 30 and consumed by the owner of the store 30. The storage 40 is stored in the main body 31, that is, the reservoir 30 from the opening 32 in a state where the detection device 20 is removed from the opening 32.

● Operation of detection system ●
Next, regarding the operation of the detection system 1, the detection device 20 is attached to each of a plurality of outdoor-installed kerosene home tanks (reservoirs) 30 (1), 30 (2),. An example of detecting (monitoring) the amount of kerosene 40 (1-n) stored in each reservoir 30 (1-n) will be described. That is, for example, the detection device 20 (1) is attached to the reservoir 30 (1), and the detection device 20 (n) is attached to the reservoir 30 (n).

Here, n is an integer of 1 or more. When the detection devices 20 (1-n) are collectively referred to without being distinguished, they are collectively referred to as the detection device 20. It may be collectively without distinguishing reservoir 30 (1-n), collectively referred to as the reservoir 30. When the kerosene 40 (1-n) is collectively referred to without distinction, the kerosene 40 is generically named. Kerosene 40 is an example of a store 40 in the present invention.

-Operation | movement of a detection apparatus First, operation | movement of the detection apparatus 20 is demonstrated.

  The detection device 20 measures the distance from the first detection unit 251 to the liquid level of the kerosene 40 stored in the reservoir 30 at a predetermined timing, and transmits the measurement result (detection result) to the server 10 at the predetermined timing. . The detection device 20 operates based on a predetermined operation mode. The “operation mode” is an operation state in which the detection device 20 can perform a predetermined function. The operation mode includes a sleep mode, an update mode, a detection mode, and a communication mode. The operation mode is switched by control of the power supply management unit 23 and the power supply unit 24.

  The “sleep mode” is an operation mode in which power is supplied only to the minimum circuit necessary for waiting in a state where the detection device 20 can be immediately activated. When the operation mode is the sleep mode, the power from the power supply unit 24 is supplied only to the power supply management unit 23. The detection device 20 normally operates in a sleep mode. Therefore, power consumption of the detection device 20 is reduced.

  The “update mode” is an operation mode in which the detection apparatus 20 updates the control information received from the server 10. When the operation mode is the update mode, the power from the power supply unit 24 is supplied to the power supply management unit 23, the storage unit 26, and the control unit 27. Here, the supply destination of power from the power supply unit 24 is switched by the control of the switch 232 of the power supply management unit 23 based on the operation mode.

  The “detection mode” is an operation mode in which the detection device 20 detects the stored item 40 and the temperature outside the reservoir 30 based on the control information. When the operation mode is the detection mode, power from the power supply unit 24 is supplied to the power supply management unit 23, the detection unit 25, the storage unit 26, and the control unit 27.

  “Communication mode” is an operation mode in which the detection device 20 transmits and receives packets to and from the server 10. When the operation mode is the communication mode, power from the power supply unit 24 is supplied to the power supply management unit 23, the storage unit 26, the control unit 27, and the communication unit 28.

  FIG. 8 is a flowchart showing the operation of the detection device 20.

  First, the power supply management unit 23 determines whether or not the current time is the detection timing (S100).

  As described above, the “detection timing” is a timing (time interval) at which the detection unit 25 detects a detection target. That is, the detection timing is a timing at which the first detection unit 251 detects the kerosene 40 and a timing at which the second detection unit 252 detects the temperature outside the reservoir 30. The detection timing is stored in the storage unit 26 as control information. The power supply management unit 23 determines whether the current time is the detection timing based on the time count value by the RTC 231.

  When the current time is the detection timing (“Yes” in S101), the power supply management unit 23 controls the switch 232 to send the detection unit 25, the storage unit 26, and the control unit 27 from the power supply unit 24. Supply power. At this time, the operation mode of the detection device 20 is switched from the sleep mode to the detection mode (S102).

  On the other hand, when the current time is not the detection timing (“No” in S101), the power supply management unit 23 maintains the sleep mode.

When the operation mode is switched to the detection mode (S102), the first detection unit 251 measures the distance from the first detection unit 251 to the liquid level of the kerosene 40, and the second detection unit 252 is the temperature outside the reservoir 30. Is measured (S103). That is, the detection result of the first detecting unit 251, Ri Ah at a distance from the first detecting unit 251 to the liquid surface, the detection result of the second detecting unit 252 is an external temperature of the reservoir 30.

  The measurement result (detection result) of the first detection unit 251 is associated with the measurement result (detection result) of the second detection unit 252 and the time measured by the first detection unit 251 and the second detection unit 252. And stored in the DB 21 of the storage unit 26 (S104). The time is calculated by the control unit 27 based on the count value of the RTC 231, for example.

FIG. 9 is a schematic diagram illustrating an example of information stored in the DB 21.
“ID” is identification information used by the detection system 1 to identify the detection device 20 (reservoir 30). For example, the serial number of the detection device 20 or a user of the detection system 1 is arbitrarily determined. An ID such as a numerical value. “Time” is the time when the first detection unit 251 and the second detection unit 252 measure the measurement (detection) target. “Distance” is the distance from the first detection unit 251 to the liquid level of the kerosene 40 measured by the first detection unit 251. “Temperature” is the temperature outside the reservoir 30 measured by the second detector 252. The time, distance, and temperature are stored in association with the DB 21. The figure shows that, for example, time “A”, distance “X1”, and temperature “Y1” are associated and stored in the DB 21. The detection device 20 can read the distance and temperature stored in the storage unit 26 in association with the time by referring to the time.

Returning to FIG.
Next, the power supply management unit 23 controls the switch 232 to stop the supply of power from the power supply unit 24 to the detection unit 25, the storage unit 26, and the control unit 27. At this time, the operation mode of the detection device 20 is switched from the detection mode to the sleep mode (S105).

  Next, the power supply management unit 23 determines whether or not the current time is a transmission timing (S106).

  The “transmission timing” is a timing (time interval) at which the communication unit 28 transmits the detection result to the server 10 as described above. The transmission timing is stored in the storage unit 26 as control information. The power supply management unit 23 determines whether or not the current time is the transmission timing based on the time count value by the RTC 231.

  When the current time is the transmission timing (“Yes” in S106), the power supply management unit 23 controls the switch 232 to the storage unit 26, the control unit 27, and the communication unit 28 from the power supply unit 24. Supply power. At this time, the operation mode of the detection device 20 is switched from the sleep mode to the communication mode (S107).

  When the operation mode is switched to the communication mode (S107), the control unit 27 compares the first reference value V1 with the temperature of the communication module 281 (the temperature of the circuit in the communication module) (S108). The “first reference value V1” is a lower limit value (temperature) of a temperature range in which a circuit (not shown) included in the communication module 281 can stably operate, or a value (temperature) obtained by adding a margin to the lower limit value. . The temperature of the communication module 281 is measured by, for example, a temperature sensor (not shown) mounted on the circuit of the communication module 281.

  Note that the temperature of the communication module may be substituted with, for example, the temperature outside the tank that was last measured by the second detection unit in the detection mode. In this case, the power supply management unit may supply power from the power supply unit to the detection unit.

When the temperature of the communication module 281 is lower than the first reference value V1 (“No” in S108), the power supply management unit 23 supplies power to the entire circuit of the communication module 281 (S109), and the temperature of the communication module 281 is reached. The temperature of the circuit of the communication module 281 is increased until becomes greater than the first reference value V1.

  On the other hand, when the temperature of the communication module 281 is equal to or higher than the first reference value V1 (“Yes” in S108), the control unit 27 reads the DB 21 from the storage unit 26 and generates a packet storing the detection result (S110). The detection result stored in the packet is a detection result stored in the DB 21 at a time between the previous transmission timing and the current transmission timing.

  Next, the communication unit 28 transmits the packet to the server 10 (S111). That is, the communication unit 28 transmits the detection result stored in the storage unit 26 to the server 10. At this time, if there is update control information to be described later in the server storage unit 13 of the server 10, the communication unit 28 receives the update control information from the server 10 (S111).

  When the update control information is not received (“No” in S112), the power supply management unit 23 controls the switch 232 to connect to the detection unit 25, the storage unit 26, the control unit 27, and the communication unit 28. The power supply from the power supply unit 24 is stopped. At this time, the operation mode of the detection device 20 is switched from the communication mode to the sleep mode (S113).

  On the other hand, when the update control information is received (“Yes” in S112), the power supply management unit 23 controls the switch 232 to supply power from the power supply unit 24 to the storage unit 26 and the control unit 27. To do. At this time, the operation mode of the detection device 20 is switched from the transmission mode to the update mode (S114).

  Next, the control unit 27 updates the control information stored in the storage unit 26 based on the received update control information (S115). That is, the detection timing and the transmission timing are updated. After the update, the detection device 20 operates based on the updated control information.

  Next, the power supply management unit 23 controls the switch 232 to stop the supply of power from the power supply unit 24 to the storage unit 26 and the control unit 27. At this time, the operation mode of the detection device 20 is switched from the update mode to the sleep mode (S116).

  Thus, the detection unit 25 measures the distance from the first detection unit 251 to the liquid level of the kerosene 40 and the temperature outside the reservoir 30 based on the detection timing. The communication unit 28 transmits the detection result to the server 10 based on the transmission timing. The detection device 20 switches the operation mode based on the detection timing and the transmission timing. That is, the detection device 20 supplies power from the power supply unit 24 to the detection unit 25 and the communication unit 28 only at a necessary timing. As a result, the power consumption of the detection device 20 is suppressed.

● Operation of Server 10 Next, the operation of the server 10 will be described.

  FIG. 10 is a flowchart showing the operation of the server 10.

  First, the server communication unit 11 receives a detection result from the detection device 20 (S201). At this time, if the server storage unit 13 has the update control information (“Yes” in S202), the server control unit 12 generates a packet storing the update control information (S203). The server communication unit 11 transmits the packet to the detection device 20 that needs to update the control information (S204).

  On the other hand, when there is no update control information in the server storage unit 13 (“No” in S202), the server control unit 12 stores the received detection result in the DB 11 and DB 12 of the server storage unit 13 (S205).

FIG. 11 is a schematic diagram illustrating an example of information stored in the DB 11.
DB11 memorize | stores the distance measured at the specific time (detection timing) of each measurement day for every day among the distances which each detection apparatus 20 measured, for example. “Measurement date” is the date when each detection device 20 measures the distance.

  The measurement date (time) and the distance are stored in association with the DB 11. For example, for the detection device 20 with ID “001”, the measurement date “2/1” and the distance “35”, the measurement date “1/31” and the distance “34”, and the measurement date “1/24” are shown. "And the distance" 27 "are associated with each other and stored in the DB 11. The server 10 can read the measurement date and distance stored in the server storage unit 13 in association with the ID by referring to the ID.

FIG. 12 is a schematic diagram illustrating an example of information stored in the DB 12.
DB12 memorize | stores the temperature measured at the specific time (detection timing) of each measurement day among the temperature which each detection apparatus 20 measured, for example per day.

  In the DB 12, an ID, a measurement date (time), and a temperature are stored in association with each other. For example, for the detection device 20 with ID “001”, the measurement date “2/1” and temperature “5”, the measurement date “1/31” and temperature “4”, and the measurement date “1/24” are shown. "And the temperature" 4 "are associated with each other and stored in the DB 12. The server 10 can read the measurement date and temperature stored in the server storage unit 13 in association with the ID by referring to the ID.

Returning to FIG.
Next, the server control unit 12 compares the detection result with the reference value (S206). That is, for each ID, the server control unit 12 compares the distance with the second reference value V2, and compares the temperature with the third reference value V3. Here, the distance compared with the second reference value V2 (temperature compared with the third reference value V3) is the distance (temperature) measured at the latest time (the latest time of comparison).

  The “second reference value V2” and the “third reference value V3” are reference values for changing detection timing and transmission timing. That is, for example, the detection timing and the transmission timing are changed based on the distance with respect to the second reference value V2 and the temperature level with respect to the third reference value V3, as will be described later. The second reference value V2 and the third reference value V3 are stored in the server storage unit 13.

  Next, the server control unit 12 generates control information based on the comparison result between the detection result and the reference value (S207). That is, for example, when the distance is equal to or greater than the second reference value V2 or when the temperature is lower than the second reference value V2, the server control unit 12 advances the detection timing (transmission timing) (shortens the timing interval). Generate control information. On the other hand, when the distance is smaller than the second reference value V2 or when the temperature is greater than or equal to the second reference value V2, the server control unit 12 delays the detection timing (transmission timing) (extends the timing interval). Is generated. The “timing interval” is an interval between a certain detection timing (transmission timing) and the next detection timing (transmission timing).

  As described above, the server control unit 12 generates control information based on the comparison result between the detection result and the reference value, that is, the detection result. That is, the detection timing (transmission timing) is determined based on the detection result (the distance measured by the first detection unit 251 and the temperature measured by the second detection unit 252). As a result, for example, when the storage amount of kerosene 40 is large, the detection device 20 detects the kerosene 40 at a relatively long timing interval (transmits the detection result), and when the storage amount is small, the detection device 20 detects the kerosene 40 at a relatively short timing interval. Kerosene 40 is detected (detection result is transmitted). That is, the detection device 20 realizes efficient detection of kerosene 40 and efficient transmission of detection results.

  On the other hand, the detection device 20 detects the kerosene 40 at a relatively short timing interval (for example, 1 hour) at a time when the kerosene 40 is frequently used, for example, in winter, and the usage frequency of the kerosene 40 in the autumn is high. At a low time, the kerosene 40 is detected at a relatively long timing interval (for example, 12 hours). Similarly, for example, the detection device 20 transmits the detection result at a relatively short timing interval (for example, one day) at a time when the kerosene 40 is frequently used, such as in winter, and the use frequency of the kerosene 40, such as in autumn. When there is little time, the detection result is transmitted at a relatively long timing interval (for example, one week). That is, the detection device 20 realizes efficient detection of kerosene 40 and efficient transmission of detection results.

  Note that the control information may be generated based only on the comparison result between the distance and the second reference value, or may be generated based only on the comparison result between the temperature and the third reference value.

  In addition, the server control unit in the present invention may compare a plurality of reference values with distances and temperatures. That is, for example, the server control unit may determine one detection timing (transmission timing) from among a plurality of detection timings (transmission timings) corresponding to a plurality of reference values, or the detection timing (transmission timing). Timing) may be determined in stages.

  Next, the server control unit 12 updates the control information stored in the server storage unit 13 with the generated control information (S208). That is, the server storage unit 13 stores updated control information (update control information).

  Next, the server control unit 12 generates detection information based on the detection result stored in the server storage unit 13 (S209). The detection information is stored in the DB 13 of the server storage unit 13 (S210).

FIG. 13 is a schematic diagram illustrating an example of information stored in the DB 13.
In the DB 13, an ID, detection information, and notification information are stored in association with each other.

  “Detection information” is the amount (value) of the amount of kerosene 40 calculated based on the detection result, the predicted value of the stored amount, the decrease value of the stored amount, the average usage (day / week / month), etc. Or information indicating a scheduled refueling date calculated based on the calculated storage amount, decrease amount, or the like.

  “Notification information” is information notified from the server 10 to the user of the server 10 such as the presence or absence of an alert or transmission restriction information.

  The “alert” is information generated by the server control unit 12 when, for example, a storage amount, a predicted value, a decrease amount, or the like exceeds a predetermined threshold.

  “Transmission restriction information” is information indicating restrictions on transmission of notification information, which will be described later, such as going out for a long period of time, cleaning of the reservoir 30, and stopping of the kerosene 40 transaction. That is, the server control unit 12 does not transmit the notification information even when an alert is generated for an ID whose transmission restriction information is “present”. The transmission restriction information is input from, for example, a vendor of kerosene 40 via the external device 50 and stored in the server storage unit 13.

  The figure shows, for example, the storage amount “240”, the predicted value “220”, the decrease value “1”, the average usage amount “2”, the scheduled refueling date “2 /” for the detection device 20 (1) with ID “001”. 15 ”, alert“ none ”, and transmission restriction“ none ”are associated and stored in the DB 13. By referring to the ID, the server 10 can read the storage amount, the predicted value, the decrease value, the average usage amount, the scheduled refueling date and the like stored in the DB 13 in association with the ID.

  The “storage amount” is the storage amount of kerosene 40 stored in the reservoir 30, that is, the remaining amount of kerosene 40. The storage amount is calculated based on the detection result and the DB 14. The DB 14 is information used by the server 10 to calculate the amount of kerosene 40 stored, and is stored in the server storage unit 13.

FIG. 14 is a schematic diagram illustrating an example of information stored in the DB 14.
In the DB 14, an ID, a capacity of the reservoir 30, and a dimension of the reservoir 30 are stored in association with each other. In the figure, for example, regarding the detection device 20 (1) with ID “001”, the capacity “490” and the dimensions “x1, y1, z1” of the width, depth, and height of the reservoir 30 are associated with each other. Indicates that it is stored in DB14. By referring to the ID, the server 10 can read the capacity and dimensions stored in the DB 14 in association with the ID. For example, the server 10 calculates “x1” × “y1” × “z1− (distance calculated by the detection device 20)” to calculate the storage amount.

  The “predicted value” is a predicted value of the storage amount of kerosene 40 after a predetermined period of time such as three days later. The predicted value is calculated based on the detection result and the DB 14. For example, the server 10 calculates “storage amount” − (“average value of distances calculated by the daily detection device 20” × “number of days”) to calculate the storage amount.

  The “decrease value” is a value obtained by reducing the amount of kerosene 40 stored within a predetermined period, for example, within two days. The decrease value is calculated based on the detection result and the DB 14. For example, the server 10 calculates “a storage amount before a predetermined period” − “latest storage amount” to calculate a decrease value.

Returning to FIG.
Next, the server control unit 12 compares the decrease value with the fourth reference value V4 and the fifth reference value V5 (S211). The “fourth reference value V4” and the “fifth reference value V5” are reference values for the server control unit 12 to determine whether or not the decrease value has suddenly increased or decreased rapidly. is there. The “fourth reference value V4” and the “fifth reference value V5” are examples of reference values in the present invention, and are stored in the server storage unit 13.

  When the decrease value is equal to or less than the fourth reference value V4 or the decrease value is equal to or greater than the fifth reference value V5 (“Yes” in S211), the server control unit 12 generates notification information (S212).

  “Notification information” is information for notifying, for example, the fact that the amount of decrease in kerosene 40 has suddenly increased, or the fact that the amount has rapidly decreased. When the notification information is generated, the detection system 1 may cause the kerosene 40 to be stolen or the kerosene 40 to leak from the reservoir 30, or the accident may have occurred to the owner of the reservoir 30. For example, it can be notified to the seller of the kerosene 40.

  Next, the server communication unit 11 transmits notification information to the external device 50 based on the address information of the external device 50 and the transmission restriction information (S213). At this time, when the decrease value that is the basis for generating the notification information is associated with the transmission restriction information “present”, the server communication unit 11 does not transmit the notification information to the external device 50. That is, for example, the server communication unit 11 transmits notification information for the detection device 20 (2) with the ID “002” illustrated in FIG. 13 to the external device 50, and notification for the detection device 20 (n) with the ID “n”. Information is not transmitted to the external device 50.

  The “address information of the external device 50” is information used by the server 10 to transmit notification information to the external device 50, and is information related to the address of the external device 50 such as a mail address or an IP address of the external device 50. . The address information is stored in the server storage unit 13.

  On the other hand, when the decrease value is between the fourth reference value V4 and the fifth reference value V5 (“No” in S211), the operation of the server 10 returns to the process (S201).

Summary According to the embodiment described above, the detection device 20 includes the detection unit 25, the storage unit 26, the communication unit 28, and the coupling unit 211 coupled to the opening 32 of the reservoir 30. It becomes. Therefore, the detection device 20 is attached to the opening 32 instead of the lid of the opening 32 of the reservoir 30. That is, the detection device 20 functions as a lid for the opening 32 of the reservoir 30. As a result, the detection device 20 can be easily attached to the reservoir 30 without drilling the existing reservoir 30 or installing a dedicated fixing member.

  In addition, the detection device 20 detects the stored item 40 stored in the reservoir 30 and transmits the detection result to the server 10. Therefore, the storage amount (remaining amount) of the stored item 40 stored in the storage unit 30 can be managed in an integrated manner.

  Further, according to the embodiment described above, the detection device 20 can be attached to and detached from the opening 32. Therefore, the detection device 20 is easily removed from the opening 32. Therefore, the detection apparatus 20 is removed from the opening part 32, and the store 40 is easily supplied (stored) from the opening part 32 to the main-body part 31 (reservoir 30).

  Furthermore, according to embodiment described above, the 1st detection part 251 measures the distance from the 1st detection part 251 to the liquid level of the stored thing 40, and the communication part 25 is liquid from the 1st detection part 251. The distance to the surface is transmitted to the server 10 as a detection result. Therefore, the detection device 20 functions as a lid of the reservoir 30 and also functions as a liquid level gauge (a fuel gauge) of the reservoir 30.

  Furthermore, according to the embodiment described above, the detection device 20 includes the case 21 that houses the detection unit 25, the storage unit 26, and the communication unit 28. The coupling portion 211 is a female screw disposed on the inner peripheral surface of the case 21 and is coupled to a male screw (coupling portion 321) disposed on the outer peripheral surface of the opening 32. That is, the shape and standard of the female screw that is the coupling portion 211 of the detection device 20 are the same as the shape and standard of the female screw of the lid of the opening 32. That is, the detection device 20 can be replaced with a lid of the opening 32. As a result, the detection device 20 can be easily attached to the reservoir 30 without drilling the reservoir 30 or installing a dedicated fixing member.

  Furthermore, according to the embodiment described above, the first detection unit 251 detects the storage 40 based on the detection timing, and the communication unit 28 transmits the detection result based on the transmission timing. Therefore, the capacity of the detection result stored in the storage unit 26 is suppressed compared to the case where the stored item is always detected. Moreover, compared with the case where a detection result is always transmitted to the server 10, the communication load of the detection apparatus 20 is reduced.

  Furthermore, according to the embodiment described above, the detection timing (transmission timing) is determined based on the detection result. That is, for example, when the distance is short (small), the timing interval of detection timing (transmission timing) is extended, and when the distance is long (large), the same timing interval is shortened. Therefore, for example, when the storage amount of the storage product 40 is large, the detection device 20 detects the storage product 40 (transmits the detection result) at a relatively long timing interval, and when the storage amount is small, the detection device 20 has a relatively short timing interval. Then, the stored item 40 is detected (detection result is transmitted). As a result, the detection device 20 realizes efficient detection of the stored item 40 and efficient transmission of the detection result.

  Furthermore, according to the embodiment described above, the detection device 20 includes the second detection unit 252 that detects the temperature outside the reservoir 30. Therefore, the detection device 20 functions as a lid for the reservoir 30 and also functions as a thermometer for the reservoir 30.

  Furthermore, according to the embodiment described above, the detection timing (transmission timing) is determined based on the temperature detected by the second detection unit 252. Therefore, for example, the detection device 20 detects (sends a detection result) the storage product 40 at a relatively short timing interval at a time when the storage product 40 is frequently used such as in winter, and the storage device 40 in the autumn season or the like. When the usage frequency is low, the stored item 40 is detected (a detection result is transmitted) at a relatively long timing interval. As a result, the detection device 20 realizes efficient detection of the stored item 40 and efficient transmission of the detection result.

  Furthermore, according to the embodiment described above, the detection system 1 includes the detection device 20 and the server 10 that receives the detection result from the detection device 20. The server 10 includes a server storage unit 13 that stores a detection result, a server control unit 12 that generates detection information based on the detection result, and a server communication unit 11 that transmits the detection information to the external device 50. Therefore, the detection system 1 can centrally manage the storage amount (remaining amount) of the stored items 40 stored in the respective reservoirs 30.

  Furthermore, according to the embodiment described above, the server 10 generates detection information (a storage amount and a predicted value thereof) based on the detection result, and transmits the detection information to the external device 50. Therefore, a user of the external device 50 such as a seller of the stored product (kerosene) 40 constructs a sales route for the efficient stored product (kerosene) 40, or sells the efficiently stored product (kerosene) 40 ( Customer) can be managed. As a result, for example, in the suburbs or depopulated areas of cold regions, efficient delivery of the stored item (kerosene) 40 becomes possible, and the delivery cost of the stored item (kerosene) 40 is reduced.

  Furthermore, according to the embodiment described above, the server control unit 12 generates notification information based on the comparison result between the decrease value and the reference value (the fourth reference value and the fifth reference value). The server communication unit 11 transmits the notification information to the external device 50 based on the address information and the transmission restriction information. For this reason, the user of the external device 50 provides a service to watch over the customer, such as contacting the possibility of theft or leakage of the stored item 40 and contacting the customer for confirmation of the customer's safety. Can do.

  In the embodiment described above, the detection result transmitted by the detection device 20 is the distance from the first detection unit 251 to the liquid level of the stored item 40. Instead of this, the detection result according to the present invention may be, for example, the storage amount of the storage in the reservoir calculated by the control unit based on the distance from the first detection unit to the liquid level. In this case, the load of the server storage amount calculation process is reduced.

  In the embodiment described above, the server 10 determines the detection timing and the transmission timing based on the detection result received from the detection device 20. Instead of this, the detection device according to the present invention may determine the detection timing and the transmission timing based on the detection result detected by the first detection unit.

  Furthermore, in the embodiment described above, the detection unit 25 includes a first detection unit 251 and a second detection unit 252. Instead of this, the detection unit in the present invention may include only the first detection unit that detects the stored item, or another sensor (for example, a gas sensor that detects the gas concentration inside the reservoir). May be provided.

  Furthermore, in the embodiment described above, the coupling portion 211 is constituted by a female screw formed integrally with the case 21 on the inner peripheral surface of the case 21. Instead of this, the connecting portion in the present invention may be a separate body from the case. That is, for example, the coupling portion in the present invention may be at least one attachment coupled to the opening end of the case and the opening of the reservoir. In this case, for example, by selecting an attachment corresponding to the diameter and shape of the opening of the reservoir, the detection device according to the present invention can be attached to a reservoir having openings of various diameters and shapes.

  Furthermore, the detection system according to the present invention may generate notification information corresponding to a specific detection device based on detection results from a plurality of detection devices. That is, for example, the detection system manages a plurality of reservoirs as one group, and when the storage amount of a specific reservoir out of the reservoirs constituting the group disappears, another reservoir (the entire group) An alert may be generated for.

  Furthermore, the detection system according to the present invention may calculate the supply amount of the stored product to the reservoir corresponding to each detection device so that the storage amount becomes “0” on a specific day. In other words, for example, the detection system is configured so that the kerosene in the reservoir disappears at the time when the kerosene is not used, or so that the storage amount is always close to the full amount for stockpiling to disasters, etc. The supply amount of kerosene may be calculated.

  Furthermore, the detection system according to the present invention may calculate a predicted value, a scheduled refueling date, and the like based on information such as a weather forecast and traffic information.

  Furthermore, the detection system according to the present invention specifies the position information of the detection device from the information of the base station via the radio wave from the detection device, and whether or not the installation position of the detection device is changed (the detection device). It may be determined whether there is any theft or movement.

  Furthermore, the detection system according to the present invention may transmit detection results instead of detection information to an external device. In this case, the user of the external device can generate necessary detection information based on the detection result from the detection system.

DESCRIPTION OF SYMBOLS 1 Detection system 10 Server 11 Server communication part (server transmission part)
12 server control unit 13 server storage unit 20 detection device 21 case 211 coupling unit 251 first detection unit (detection unit)
252 Second detection unit 26 Storage unit 27 Control unit 28 Communication unit (transmission unit)
30 Storage 32 Opening 40 Storage 50 External Device

Claims (20)

A sensing device attached to a reservoir with an opening,
A detection unit for detecting a stored item stored in the reservoir from the opening;
A storage unit for storing a detection result of the detection unit and a temperature reference value ;
A transmission unit for transmitting the detection result stored in the storage unit;
A power feeding unit that supplies power to the transmission unit;
A power supply management unit that manages supply of the power from the power supply unit to the transmission unit;
A coupling portion coupled to the opening;
Ri name have,
The power supply management unit compares the temperature of the transmission unit with the temperature reference value, and when the temperature of the transmission unit is lower than the temperature reference value, until the temperature of the transmission unit becomes higher than the temperature reference value Supplying the power to the transmitter;
A detection device characterized by that. A temperature sensor for measuring the temperature of the transmitter,
With
The power supply management unit supplies the power to the transmission unit based on the temperature of the transmission unit measured by the temperature sensor.
The detection device according to claim 1. The coupling portion is detachable from the opening.
The detection device according to claim 1. The store is liquid,
The detection unit measures the distance from the detection unit to the liquid level of the stored item,
The detection device according to claim 1. The detection result is a distance from the detection unit to the liquid level.
The detection device according to claim 4 . The detection result is a storage amount of the stored matter calculated based on a distance from the detection unit to the liquid level.
The detection device according to claim 4 . A case for accommodating the detection unit, the storage unit, the transmission unit, the power supply unit, and the power supply management unit ;
With
The coupling portion is a female screw disposed on the inner peripheral surface of the case, and is coupled to a male screw portion disposed on the outer peripheral surface of the opening.
The detection device according to claim 1. The storage unit stores a detection timing indicating a timing at which the detection unit detects the stored item,
The detection unit detects the stored item based on the detection timing stored in the storage unit.
The detection device according to claim 1. The detection timing is determined based on the detection result.
The detection device according to claim 8 . A second detector for detecting a temperature outside the reservoir;
With
The detection timing is determined based on the temperature detected by the second detection unit.
The detection device according to claim 8 . The storage unit stores a transmission timing indicating a timing at which the transmission unit transmits the detection result,
The transmission unit transmits the detection result based on the transmission timing stored in the storage unit.
The detection device according to claim 1. The transmission timing is determined based on the detection result.
The detection device according to claim 11 . A second detector for detecting a temperature outside the reservoir;
With
The transmission timing is determined based on the temperature detected by the second detector.
The detection device according to claim 11 . A detection device that is attached to a reservoir having an opening, and detects a stored product stored in the reservoir from the opening;
A server that receives the detection result of the stored item detected by the detection device from the detection device;
Having
The detection device is the detection device according to any one of claims 1 to 13 .
A detection system characterized by that. The server
A server storage unit for storing the detection result received from the detection device;
A server control unit that generates detection information based on the detection result;
A server transmission unit for transmitting the detection information to an external device;
Comprising
The detection system according to claim 14 . The server control unit calculates a predicted value of the storage amount of the stored item based on the detection result.
The detection system according to claim 15 . The server control unit generates control information for controlling the operation of the detection device based on the detection result.
The detection system according to claim 15 . The control information includes at least one of a timing at which the detection device detects the stored item and a timing at which the detection device transmits the detection result.
The detection system according to claim 17 . The server storage unit stores a reference value,
The server control unit
Based on the detection result, calculate a decrease value of the storage amount of the storage,
Based on a comparison result between the decrease value and the reference value, to generate notification information,
The detection system according to claim 15 . The server storage unit stores address information of the external device and transmission restriction information of the notification information,
The server transmission unit transmits the broadcast information based on the address information and the transmission restriction information.
The detection system according to claim 19 .

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