JP2018147204A - Waste oil managing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a waste oil managing system capable of presenting an amount of carbon dioxide produced in reproduction processing of a waste oil.SOLUTION: The kind of a collected waste oil and the amount of the waste oil are input by an operating display unit 10 of a terminal device 5, and a collection location of the waste oil and a delivery location of a reproduced oil that is the collected waste oil having undergone reproduction processing are specified by a GPS receiver 20, and are input to a server 50 via an internet 60. The server 50 calculates an emission amount of COproduced when the reproduction processing is performed on the waste oil in accordance with the input kind of the waste oil and the amount of the waste oil, and calculates an emission amount of COproduced when the waste oil and the reproduced oil are delivered on the basis of the collection location of the waste oil and the delivery location of the reproduced oil. Next, the calculated emission amount of COis transmitted to the terminal device 5 via the internet 60, and the amount of COdischarged from the collection of the wasted oil to the delivery as the reproduced oil.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a waste oil management system that calculates an amount of carbon dioxide generated when waste oil is recovered, regenerated, and delivered.

  Conventionally, in order to perform energy saving management of buildings and facilities managed by companies and organizations, carbon dioxide emissions are calculated from energy consumption including water consumption, and carbon dioxide after a certain period of time has elapsed. Estimate the amount of emissions, further authenticate as carbon dioxide emission figures, and automatically trade the certified carbon dioxide emission rights through the network in the carbon emission trading market. The bank account details related to carbon dioxide emissions and carbon dioxide emission trading are browsed in real time by terminal devices on the network of related parties, and the carbon dioxide emissions after a certain period of time have reached the reference value. There is an energy-saving management system that sends an alarm to terminal devices on the network of the parties concerned (for example, patents) Document reference 1).

JP 2009-230237 A

  However, in the conventional energy saving management system described above, the amount of carbon dioxide emitted is calculated from the energy consumption of the facility to be managed. However, when waste oil is recovered and regenerated, the regenerated oil is generated. It did not calculate the amount of carbon dioxide generated. That is, there is a problem that the management target of carbon dioxide emission cannot be managed by the type or amount of waste oil.

  This invention is made | formed in view of such a problem, and it aims at providing the waste oil management system which can show the quantity of the carbon dioxide which generate | occur | produces in the regeneration process of waste oil.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following application examples. Note that the reference numerals in parentheses and supplementary explanations in this column show the correspondence with the embodiments described later in order to help understanding of the present invention, and do not limit the present invention at all. .

[Application Example 1]
The waste oil management system (1) according to the present invention includes an input unit (10) for inputting the type of recovered waste oil and the amount of waste oil, the type of waste oil input by the input unit (10), and the waste oil. A calculation unit (50) for calculating the amount of carbon dioxide generated when the waste oil is regenerated from the amount of the output, and an output unit (10) for outputting the amount of carbon dioxide calculated by the calculation unit (50), The main point is that

  In such a waste oil management system (1), when the waste oil is recovered, the type and amount of the waste oil are input from the input unit (10). Then, in the calculation unit (50), the amount of carbon dioxide generated when the waste oil is regenerated is calculated from the type and amount of the waste oil.

  Accordingly, the calculated amount of carbon dioxide is output by the output unit (10), and the output result is presented to, for example, the factory or business establishment that is the waste oil collection destination, and discharged from the factory or business establishment. The amount of carbon dioxide can be managed.

  In addition, by managing the amount of carbon dioxide to be discharged, it becomes possible to reduce the amount of waste oil discharged from factories and offices, and hence the amount of carbon dioxide.

[Application Example 2]
A waste oil management system (1) according to the present invention is the waste oil management system (1) described in Application Example 1, wherein a recovery position specifying unit (20) for specifying a recovery position of the waste oil and the recovered waste oil are A delivery position specifying unit (20) for specifying the delivery position of the regenerated recycled oil, and the calculation unit (50) includes the recovery position of the waste oil specified by the recovery position specifying unit (20) Based on the delivery position of the recycled oil specified by the delivery position specifying unit (20), the gist is to calculate the amount of carbon dioxide generated when the waste oil and the recycled oil are conveyed.

  In such a waste oil management system (1), the collection position specifying unit (20) and the delivery position specifying unit (20) can specify the collection position of the waste oil and the delivery position of the recycled oil. Therefore, for example, based on the map data, the distance between the collection position and the delivery position or the transportation route of the transit point such as the recycling factory is calculated, and the calculated distance and the conveying means (private vehicle, truck) for conveying the waste oil or the recycled oil The amount of carbon dioxide emitted during transportation can be calculated based on the amount of carbon dioxide emitted per distance of a train or a train.

  Therefore, in the output, the amount of carbon dioxide generated when the waste oil is regenerated and the amount of carbon dioxide generated when the waste oil and the recycled oil are conveyed can be managed, and the carbon dioxide emission amount with higher accuracy can be controlled. Management becomes possible, and as a result, more carbon dioxide can be reduced.

It is a block diagram which shows the structure of the outline of a waste oil management system. It is a block diagram which shows the structure of the outline of a terminal device. It is a flowchart which shows the flow of the control process (terminal process) in a terminal device. It is a flowchart which shows the flow of the waste oil information acquisition process in a terminal device. It is a flowchart which shows the flow of the waste oil collection | recovery / delivery position specific process in a terminal device. It is a flowchart which shows the flow of the calculation result display process in a terminal device. In the server, it is a flow chart showing the flow of CO ₂ emission calculating process. Is a diagram illustrating an example of a data CO ₂ emissions per unit quantity of discharging at the time of waste oil by type of waste oil regeneration. It is a figure which shows an example of the display content in the display screen of a terminal device.

  Embodiments to which the present invention is applied will be described below with reference to the drawings. The embodiment of the present invention is not limited to the following embodiment, and can take various forms as long as they belong to the technical scope of the present invention.

[Configuration of waste oil management system]
Based on FIG.1 and FIG.2, the structure of the waste oil management system 1 is demonstrated. FIG. 1 is a block diagram showing a schematic configuration of a waste oil management system 1 to which the present invention is applied, and FIG. 2 is a block diagram showing a schematic configuration of a terminal device 5.

As shown in FIG. 1, the waste oil management system 1 includes a terminal device 5, a server 50, and a communication network 60. In the present embodiment, since the Internet is used as a communication network, the communication network 60 is also referred to as the Internet 60 hereinafter. In the present embodiment, a plurality of terminal devices 5 are used.

As illustrated in FIG. 2, the terminal device 5 includes a control unit 7, an operation display unit 10, a GPS receiver 20, a reception unit 30, and a transmission unit 40.
The control unit 7 includes a CPU, a ROM, a RAM, and an I / O (not shown), and controls the operation display unit 10, the GPS receiver 20, the reception unit 30, the transmission unit 40, and the like by a program stored in the ROM. Do. The ROM stores various display data and map information to be displayed on the display screen 11.

The operation display unit 10 is a part for inputting the type of collected waste oil and the amount of waste oil, and includes a display screen 11 and a touch screen 12.
The display screen 11 is a screen for prompting input and displaying input results, and the touch screen 12 is mounted on the surface of the display screen 11, and various inputs can be performed by the user of the terminal device 5. It is a part to do.

  Further, on the touch screen 12, it is possible to perform an input operation for specifying the position of the terminal device 5 acquired by the GPS receiver 20 described later as a waste oil collection position or a recycled oil delivery position. Yes.

  The GPS receiver 20 is a receiver for acquiring the current position of the terminal device 5. The current position acquired by the operation of the operation display unit 10 is used to recycle the waste oil or the recovered waste oil. Can be specified as the delivery position.

  Further, the GPS receiver 20 can display the acquired current position with an icon indicating the current position on a map displayed on the display screen of the operation display unit 10 (actually, GPS The control unit 7 that has input the current position acquired by the receiver 20 via the I / O is displayed on the display screen 11).

The receiving unit 30 and the transmitting unit 40 are configured to reduce the amount of carbon dioxide (hereinafter also referred to as CO ₂ ) generated when the waste oil is regenerated, and the amount of CO ₂ generated during transportation between the collection position and the delivery position. It is a receiver and a transmitter that output to the server 50 to be described later with respect to the quantity, and input a processing result performed by the server 50.

The receiving unit 30 and the transmitting unit 40 include a built-in antenna 31 that is commonly used for transmission / reception, and performs data communication using radio waves with the Internet 60 via the built-in antenna 31. Data such as CO ₂ emissions is transmitted to and received from the server 50.

  The server 50 is a so-called server machine connected to the Internet 60, and includes a main body 51, a display 52, a keyboard 53, a printer 54, and the like as shown in FIG.

Further, the main body 51 is provided with a CPU, ROM, RAM, I / O, etc. (not shown) so that information can be transmitted to and received from the terminal device 5 via the Internet 60.

The server 50 performs the following processes (a) to (e).
(A) The type and amount of recovered waste oil are acquired from each terminal device 5 via the Internet 60.

(A) The amount of CO ₂ generated when the waste oil is regenerated is calculated from the type and amount of the obtained waste oil.

(C) The waste oil is collected from the waste oil recovery position specified by the GPS receiver 20, the recycled oil delivery position, and the factory location where the waste oil is recycled, and the recycled oil is generated from the recovered waste oil. Calculate the distance of the transport route until oil is delivered.

(D) the distance between the transport means of the calculated transport path (track in this embodiment), and a CO ₂ emissions per unit distance, calculating the amount of CO ₂ tracks to play oil delivered from waste oil recovery is discharged To do.

(E) via the transmission unit 40 and the Internet 60 to the server 50 the amount of CO ₂ generated during conveyance between the amount and the recovery position of the CO ₂ and delivery position which occurs when reproducing processing waste oil Output.

[Processing in terminal device]
Next, processing in the terminal device 5 will be described based on FIGS. FIG. 3 is a flowchart showing the flow of control processing (hereinafter referred to as terminal processing) in the terminal device 5, and FIGS. 4 to 6 show subroutines (waste oil information acquisition processing, waste oil collection / delivery position specification) during terminal processing. It is a flowchart which shows the flow of a process of a process and a calculation result display process.

(Terminal processing)
In the terminal process, the CPU of the control unit 7 of the terminal device 5 first displays an input screen on the display screen 11 in S300 as shown in FIG. The display contents will be described later with reference to FIG.

  In subsequent S305, terminal operation information is acquired. That is, it is acquired whether the user has pressed down the touch screen 12 and which position (coordinates on the touch screen 12) has been pressed down.

  Then, what terminal operation has been performed is acquired depending on which of the keyboard display corresponds to the input button displayed on the input screen displayed in S300.

  In subsequent S310, it is determined whether or not there is an input operation. That is, it is determined whether or not an input operation has been performed in S305, in other words, whether or not information indicating that the input area of the touch screen 12 has been pressed has been acquired.

  If it is determined that there is an input operation (S310: Yes), the process proceeds to S315. If it is determined that there is no input operation (S310: NO), the process returns to S300, and the input screen display is repeated.

  In S315, the type of input operation input in S305 is determined. If the input operation is waste oil information input, the process proceeds to S320. If the input operation is a position specifying input, the process proceeds to S325, and the input operation is a calculation result display. Shifts the processing to S330.

  In S320, a waste oil information acquisition process is executed. Details of the waste oil information acquisition process will be described later. In S325, waste oil collection / delivery position specifying processing is executed. Details of the waste oil recovery / delivery position specifying process will be described later. In S330, calculation result display processing is executed. Details of the calculation result display process will be described later.

(Waste oil information acquisition process)
Next, the waste oil information acquisition process will be described with reference to FIG. As shown in FIG. 4, in the waste oil information acquisition process, the CPU of the control unit 7 first performs display for inputting waste oil information on the display screen 11 in S <b> 400. The display contents are a display prompting input of “type of waste oil” and “amount of waste oil” and a display indicating the end of input. The display contents will be described later with reference to FIG.

  In subsequent S405, input information is acquired. In subsequent S410, it is determined whether or not the input information acquired in S405 is “type of waste oil”. If the input information is “type of waste oil” (S410: Yes), the process proceeds to S415. If the input information is not “type of waste oil” (S410: No), the process proceeds to S420. The display contents at this time will be described later with reference to FIG.

In S415, the type of waste oil is acquired from the input information input in S405 and stored in the RAM.
In S420, it is determined whether or not the input information acquired in S405 is “amount of waste oil”. If the input information is “amount of waste oil” (S420: Yes), the process proceeds to S425. If the input information is not “amount of waste oil” (S420: No), the process proceeds to S430.

In S425, the amount of waste oil is acquired from the input information input in S405 and stored in the RAM.
In S430, it is determined whether or not the input information acquired in S405 is the end of input. If the input information is the end of input (S430: Yes), the process proceeds to S435. If the input information is not the end of input (S430: N), the process returns to S400, and this process is repeated.

  In S435, it is determined whether both “type of waste oil” and “amount of waste oil” have been input. If both have been input (S435: Yes), the process ends. On the other hand, if either one has not been input (S435: No), the process proceeds to S440.

  In S440, a display prompting the input of “type of waste oil” and “amount of waste oil” that is not input is performed, the processing is returned to S400, and this processing is repeated.

(Waste oil recovery / delivery position identification processing)
Next, waste oil collection / delivery position specifying processing will be described with reference to FIG. As shown in FIG. 5, in the waste oil collection / delivery position specifying process, the CPU of the control unit 7 first displays a selection screen for selecting whether to collect waste oil or to deliver on the display screen 11 in S500. The display contents will be described later with reference to FIG.

  In subsequent S505, input information (selection information on whether to collect or deliver waste oil) is acquired from the touch screen 12. Specifically, the selection information is acquired depending on whether or not the coordinates at which the touch screen 12 is pressed are within the display area of the selection screen for waste oil collection or delivery displayed in S500.

  In continuing S505, it is determined whether there exists input information (selection information). That is, it is determined whether or not the coordinates in the display area of the selection screen for selecting whether to collect or deliver waste oil have been pressed on the touch screen 12.

If there is input information (S510: Yes), the process proceeds to S515. If there is no input information (S510: No), the process returns to S500 and the input process is repeated.
In S515, the current position is acquired from the GPS receiver 20.

  In subsequent S520, it is determined whether or not the input information acquired in S505 is information indicating waste oil recovery. If the information indicates waste oil recovery (S520: Yes), the process proceeds to S525. If the information does not indicate waste oil recovery (that is, information indicating the delivery of waste oil) (S520: No), the process is performed. The process proceeds to S530.

  In S525, the current position acquired in S515 is stored in the RAM as a waste oil collection position, and the process ends. In S530, the current position is stored in the RAM as a waste oil delivery position, and the process ends.

(Calculation result display process)
Next, the calculation result display process will be described with reference to FIG. As shown in FIG. 6, the CPU of the control unit 7 first obtains the calculation result of the CO ₂ emission amount from the server 50 via the Internet 60 in S600.

In subsequent S605, the calculation result of the CO ₂ emission amount acquired in S600 is displayed on the display screen 11, and then the process ends.

[Processing on the server]
(CO ₂ emission calculation processing)
Next, processing in the server 50 will be described based on FIG. FIG. 7 is a flowchart showing the flow of CO ₂ emission amount calculation processing. In the CO ₂ emission calculation process, the CPU of the main body 51 of the server 50 acquires information (hereinafter also referred to as terminal information) from the terminal device 5 in S700. The information acquired here is at least one of information of recovered waste oil (type and amount of waste oil), waste oil recovery / delivery information, and position of recovery / delivery.

  In continuing S705, it is determined whether the terminal information acquired in S700 is the information of collection | recovery waste oil. If it is determined that the information is recovered waste oil (S705: Yes), the process proceeds to S710. If it is determined that the information is not recovered waste oil (S705: NO), the process proceeds to S715.

In S710, the amount of CO ₂ emission at the time of reclaimed oil purification is calculated from the information of the recovered waste oil. Specifically, as shown in FIG. 8, the amount of waste oil recovered to the CO ₂ emission amount per unit amount of the corresponding waste oil type from the data of the CO ₂ emission amount per unit amount discharged at the time of waste oil regeneration by type of waste oil. Multiply the amount to calculate the amount of CO ₂ emitted when reclaiming the recovered waste oil.

  In S715, it is determined whether or not the terminal information acquired in S700 is information on the position of waste oil collection and the position of reclaimed oil delivery. If it is determined that the information is the position of the waste oil recovery and the position of the recycled oil delivery (S715: Yes), the process proceeds to S720, and the information is not the information of the position of the waste oil recovery and the position of the recycled oil delivery ( (S715: NO), the process proceeds to S725.

In S720, the amount of CO ₂ emission during the transport of the waste oil and the recycled oil is calculated from the information of the waste oil recovery position and the position of the recycled oil delivery. Specifically, it is calculated by the following (a) and (b)

(A) Based on the GPS position information and map data of the waste oil recovery position and the reclaimed oil entry position, the waste oil recovery is based on the position of the waste oil regeneration factory, the waste oil recovery position, and the recycled oil delivery position stored in advance in the ROM. The delivery distance in the vehicle between the position and the position of the waste oil recycling factory and between the waste oil recycling factory and the recycled oil delivery position is calculated.

(B) The CO ₂ emission amount per 1 km of the vehicle used for delivery, which is stored in advance in the ROM, and the delivery distance between the waste oil recovery position and the waste oil recycling factory, and between the waste oil recycling factory and the recycled oil delivery position. And the amount of CO ₂ emission is calculated.

  In S725, it is determined whether the information on the recovered waste oil and any information on the waste oil recovery position and the recycled oil delivery position have not been acquired. If it is determined that no information has been acquired (S725: Yes), the process returns to S700, and this process is repeated. On the other hand, if it is determined that all information has been acquired (S725: No), the process proceeds to S730.

In S730, the calculation result of the CO ₂ emission amount is stored in the RAM. In the subsequent S735, the CO ₂ emission amount stored in the RAM in S730 is output to the terminal device 5 via the Internet 60, and then the process is terminated.

[User operation]
Next, the operation of the terminal device 5 by the user will be described based on FIG. FIG. 9 is a diagram illustrating an example of display contents on the display screen of the terminal device.

(F) As shown in FIG. 9 (a), on the display screen 11 of the terminal device 5, "type of waste oil", "input of amount of waste oil", "recovery location of waste oil", and "delivery location of recycled oil" Since a selection screen is displayed, one of the display areas is pressed and one is selected.

(G) When “input waste oil type” is pressed, the oil type selection screen shown in FIG. 9B is displayed, so any one of the display areas of “bio-based oil”, “vegetable oil”, and “mineral oil” Press to select the type of waste oil.

(H) When “Waste oil amount” is pressed, the oil amount input screen shown in FIG. 9 (c) is displayed. Enter the oil amount by pressing a separate keyboard input screen (not shown). To do.

(G) When the display area of “waste oil collection position” is pressed, the current position is acquired from the GPS receiver 20 and stored in the terminal device 5 (RAM) as the waste oil collection position.

(E) When the display area of “recycled oil delivery position” is pressed, the current position is acquired from the GPS receiver 20 and stored in the terminal device 5 (RAM) as the recycled oil delivery position.

[Features of waste oil management system]
In the waste oil management system 1 having the above configuration and function, the type and amount of waste oil are input from the operation display unit 10 when the waste oil is collected. In the server 50, the amount of carbon dioxide generated when the waste oil is regenerated is calculated from the type and amount of the waste oil.

  Therefore, the calculated amount of carbon dioxide is output by the operation display unit 10, and the output result is presented to, for example, the factory or business office that is the waste oil collection destination, and discharged from the factory or business office. The amount of carbon dioxide can be managed.

In addition, by managing the amount of carbon dioxide to be discharged, it becomes possible to reduce the amount of waste oil discharged from factories and offices, and hence the amount of carbon dioxide.
In addition, the GPS receiver 20 can identify the waste oil collection position and the recycled oil delivery position. Therefore, for example, based on the map data, the distance between the collection position and the delivery position or the transportation route of the transit point such as the recycling factory is calculated, and the calculated distance and the conveying means (private vehicle, truck) for conveying the waste oil or the recycled oil The amount of carbon dioxide emitted during transportation can be calculated based on the amount of carbon dioxide emitted per distance of a train or a train.

  Therefore, in the output, the amount of carbon dioxide generated when the waste oil is regenerated and the amount of carbon dioxide generated when the waste oil and the recycled oil are conveyed can be managed, and the carbon dioxide emission amount with higher accuracy can be controlled. Management becomes possible.

[Other Embodiments]
(A) In the above embodiment, the CO ₂ emission amount calculated by the server 50 is displayed on the display screen 11 of the terminal device 5. However, a printer that can be built in or externally attached to the terminal device 5, such as a thermal printer, etc. May be output. At this time, the CO ₂ emission amount may be printed as a numerical value, or may be printed in a form that can be read by other devices such as a barcode or a QR code (registered trademark).

(A) In the above embodiment, only the calculation result of the CO ₂ emission amount is output by display or the like, but from the input information (type of waste oil, amount of waste oil, waste oil recovery position, reclaimed oil delivery position, etc.), Information regarding costs such as the cost of recycling the recovered waste oil and the cost of transportation may be output together with the CO ₂ emission amount.

(C) In the above embodiment, data of “bio-based oil”, “vegetable oil”, and “mineral oil” is used as the type of waste oil, but the type of waste oil may be further subdivided.

  DESCRIPTION OF SYMBOLS 1 ... Waste oil management system, 5 ... Terminal device, 10 ... Operation display part, 11 ... Display screen, 12 ... Touch screen, 20 ... GPS receiver, 30 ... Reception part, 40 ... Transmission part, 50 ... Server, 51 ... Main body 52 ... Display, 53 ... Keyboard, 60 ... Internet (communication network).

Claims (2)

An input unit for inputting the type of waste oil recovered and the amount of waste oil;
A calculation unit that calculates the amount of carbon dioxide generated when the waste oil is regenerated from the type of waste oil and the amount of waste oil input by the input unit;
An output unit for outputting the amount of carbon dioxide calculated by the calculation unit;
A waste oil management system characterized by comprising In the waste oil management system according to claim 1,
A collection position identifying unit for identifying the collection position of the waste oil;
A delivery position specifying unit for specifying a delivery position of the regenerated oil obtained by reprocessing the recovered waste oil;
With
The calculation unit includes:
Amount of carbon dioxide generated when transporting the waste oil and the recycled oil based on the recovery position of the waste oil specified by the recovery position specifying unit and the delivery position of the recycled oil specified by the delivery position specifying unit Waste oil management system characterized by calculating