TWI854358B - Metal recycling and re-producing carbon emission recording method - Google Patents

Abstract

A metal recycling and re-producing carbon emission recording method containing the steps of: filling a recycle material into a standard package and scanning a label on the standard package to obtain an access node of a carbon footprint report; recording a testing result of a physical or chemical property of the recycled material, a real-time image of the filling, a carbon footprint history, and a factory recycling information on the access node; recording a standard current price of the standard package, transporting and storing the standard package, and scanning the label to obtain the access node and recording the time and carbon emission to the carbon footprint report. This invention records the carbon footprint of the complete recycling process of waste materials and systematically generates open and fair recording, solving the problems of prior arts.

Description

Metal recovery and regeneration production process with carbon disclosure

A method for recycling metals, particularly a recycling method with carbon inventory and carbon disclosure.

The Oxford Dictionary's keyword of the year for 2019 is "Climate emergency", which means that extreme climate caused by global warming has been recognized by the general public as a very serious problem. Human economic activities are the culprit for the current greenhouse gas increase and greenhouse effect. Therefore, international agreements such as the Paris Agreement and the Kyoto Protocol all hope to achieve carbon peak within the agreed time so that industrial production/economic activities in domestic enterprises in various countries can achieve carbon neutrality. In order to achieve the goal of carbon neutrality and avoid the problem of increased operating costs caused by EU carbon tax issues such as CBAM, many companies have already started to reduce carbon emissions in the production process.

Although many companies want to reduce carbon emissions, most of them know very little about it and are at a loss. Most of them are still in the superficial behavior of recycling materials, planting more trees, using solar panels, etc. A responsible company must first confirm the carbon emissions of all processes in the production process to reduce carbon emissions. This is called "carbon inventory". Unfortunately, although small and medium-sized enterprises are aware of the need for inventory, the actual implementation of the inventory of the production process of the supply chain is very poor, let alone the inventory of recycled materials and regeneration processes.

In order to solve the technical problem that the existing industry lacks technology and resources for carbon inventory in the recycling process of recycled materials, resulting in the stagnation of related carbon reduction and inventory progress, affecting the overall carbon neutrality progress, The present invention proposes a metal recycling and regeneration production history method with carbon disclosure, the steps of which include: filling a recycled material into a standard package, scanning a label of the standard package to obtain an access node of a carbon data report; recording a detection result of a physical or chemical quantity of the recycled material, a real-time image of the filling, a carbon emission footprint history and a factory recycling information on the access node; recording a standard current price of the standard package, and storing the standard package in a storage space after transportation, and scanning the label to obtain the access node , record the storage time and the carbon emissions directly or indirectly generated in the storage space and store them in the carbon data report; the recycled material in the standard packaging is tested and judged to generate a purity grade of the recycled material and recorded in the carbon data report of the access node; a grade of compensation is generated based on the purity grade and with reference to the standard current price; multiple recycled materials in the standard packaging with the same physical or chemical quantity are taken and reformed and mixed through a reprocessing process, and the carbon emissions of the reprocessing process are scanned and recorded in the carbon data report; all carbon emission records of the carbon data report are evenly distributed to a recycled finished product produced by the reprocessing process, and a finished product carbon emission record, a production history and a carbon certificate are generated for the recycled finished product.

From the above description, it can be seen that the present invention has the following characteristics:

1. Completely record the carbon footprint generated by the waste recycling process, systematically generate fair and open records, comply with the ISO spirit, contribute to the fairness and credibility of future carbon certificates, and completely solve the problems of existing technologies.

2. In the recycling process, monitoring and standard packaging can be cleverly used to effectively provide production history and carbon emission records at the same time as the output of recycled products, achieving the unexpected effect of intelligent carbon inventory and tracking records.

10:Servo system

20: Applications

30: Detection device

40: Warehouse management system

50: Image capture device

60: Barcode recognition device

70: Standard packaging

A: Mobile device

Figure 1 is a schematic diagram of the system flow of a preferred embodiment of the present invention.

Please refer to FIG1, which is a metal recovery and regeneration production history system with carbon disclosure: including a servo system 10, more than one application program 20, a detection device 30, a warehouse management system 40, an image capture device 50, a barcode recognition device 60, and a plurality of standard packages 70. Each application program 20 is connected to the servo system 10 by signal, and transmits signals with the servo system 10 to complete the signal communication and control behavior with the servo system 10. Each of the detection devices 30 is connected to the servo system 10 by signal, and outputs a detection result to the servo system 10, so that the servo system 10 records the detection result, which includes but is not limited to physical or chemical quantities such as weight, material, purity, density, metallographic structure, composition, element, lattice structure, etc. In other words, the detection device 30 may be a scale, element analysis equipment, optical imaging monitoring equipment, X-ray diffraction equipment, EDS element analysis equipment, etc.

The warehouse management system 40 is signal-connected to the servo system 10, and includes a storage space for accommodating the storage, import and export, total quantity control, and management of a material, wherein the material may include different types, units, capacities, etc., which are respectively loaded into a plurality of the standard packages 70. The warehouse management system 40 also records a storage greenhouse gas emission history of each standard package 70 during the storage process. The storage greenhouse gas emission may be related to direct greenhouse gas emission, input energy (air conditioning, lighting, robot transmission, monitoring management), transportation (forklift, crane, official car, truck, tanker), other sources, etc. For example, the storage greenhouse gas emission history of each standard package 70 during the operation of the warehouse management system 40 is recorded. The servo system 10 obtains the content information and the storage greenhouse gas emission history of each standard package 70 from the warehouse management system 40.

The plurality of image capture devices 50 and the barcode recognition device 60 are used to continuously record all processes from the production to the destruction of the standard package 70, for example, they are installed in an external factory, a transport truck, the storage space, a recycling factory, etc. to handle the production, transportation, storage, and remanufacturing of the standard package 70. The plurality of image capture devices 50 and the barcode recognition device 60 are respectively connected to the servo system 10 by signal and respectively capture a digital audio and video information, recognize a label on each standard package 70, and generate an identification result, and output the identification result to the servo system 10, wherein the digital audio and video information includes but is not limited to voice, image, and photo.

Preferably, during the filling, production, use, and delivery of the standard package 70, the digital audio and video information of the image capture device 50 and the barcode recognition device 60 and the recognition result can be output to the server system 10 through the application 20. The application 20 can be installed on any mobile device A, for example, the driver in the transportation process operates the built-in image capture device 50 and the barcode recognition device 60 of the mobile device A to obtain the digital audio and video information and the recognition result respectively, and the recognition result is updated to the server system 10 through the application 20 corresponding to a carbon data report of the standard package 70.

[Implementation example] Recycling aluminum chips

A processing equipment of a CNC processing plant is installed with more than one image capture device 50 and the barcode recognition device 60, and the standard package 70 is filled with aluminum chips of fixed weight and material (for example, aluminum alloys of brands such as 7075 and 6061, 10 kg per package). The standard package 70 includes a digital label, and the digital label is, for example, a radio frequency identification label RFID, QRCODE, etc. After the barcode recognition device 60 scans and recognizes the barcode, it transmits the recording result of the digital audio and video information of the image capture device 50 back to the servo system 10, so that the factory recycling information of the aluminum chips of the standard package 70 can be updated in the servo system 10, corresponding to the carbon data report of the standard package 70. In this way, the carbon data report corresponding to each standard package 70 can start from filling the standard package 70 with recycled materials, and continue to monitor its data collection and recording process with digital audio and video information to ensure data accuracy and reduce disputes.

A Sheng Aluminum Company purchases the standard package 70 from the CNC processing plant at a standard current price, and the purchase price is recorded in the carbon data report corresponding to the standard package 70 in the servo system 10. The Sheng Aluminum Company dispatches a freight equipment to transport the standard package 70 to the warehouse management system 40 of the Sheng Aluminum Company for storage. During the process, the model, mileage, fuel consumption, etc. of the freight equipment are recorded, and after scanning the label on the standard package 70, the data is output and recorded in the carbon data report corresponding to the standard package 70.

Correspondingly, when the standard package 70 is stored in the warehouse management system 40, the monitoring data is updated in the carbon data report through imaging and code scanning. Since the weight and space of the standard package 70 are fixed, the carbon emissions of the equipment used in its transportation process can be converted and recorded in the carbon data report, and the storage time and space occupied in the warehouse are also fixed and estimable values. In this way, the carbon emissions consumed by the aluminum chips in the standard package 70 from generation, recycling and transportation to storage can be notarized and effectively recorded in its carbon data report. The carbon data report can also be used in combination with imaging recording and code scanning recognition to continuously update and record the carbon emission history of the standard package 70.

The Sheng Aluminum Company takes out the standard package 70 from the warehouse management system 40, and after a test to determine the purity and composition of the material, calibrates the purity level of the aluminum chips in the standard package 70 and records it in the carbon emission history.

Furthermore, after completing the purity grade rating, Sheng Aluminum can refer to the standard current price at the time of purchase and generate a first-level compensation corresponding to the purity grade of the aluminum chips and return it to the CNC factory.

The Sheng Aluminum Company takes aluminum chips from a plurality of standard packages 70 and processes them through a reprocessing process to remove impurities from the aluminum chips, add required elements, mix and melt them, and smelt them to form an aluminum alloy soup, which is then solidified to form an aluminum ingot. The carbon emissions directly or indirectly generated by the equipment and environment used in this reprocessing process are recorded and evenly distributed among the carbon emissions used to generate the carbon data of the aluminum ingot, which is recorded in the servo system 10. In this way, the carbon data and production history of each aluminum ingot generated from recycled aluminum chips can be effectively and systematically recorded in the servo system 10.

Furthermore, another standard package 70 and the aforementioned recording, scanning and other means can also be used to continuously record the emissions of the aluminum ingots during the sales process to the buyer, and record them in the carbon data report of the standard package 70 of the aluminum ingots. Since the records of the aforementioned process are clear and each step of the process is fairly and effectively checked and recorded, a carbon certificate can be directly produced for the product aluminum ingots when they are shipped.

Based on the above description, the present invention also discloses a metal recycling and regeneration production history method with carbon disclosure, and its steps include: Providing one or more standard packages 70, the standard package 70 includes a label; filling a recycled material into the standard package 70, and scanning a label of the standard package 70 to obtain an access node of a carbon data report, and recording a detection result of a physical or chemical quantity of the recycled material, a real-time image of the filling, a carbon emission footprint history and a factory recycling information in the access node; wherein the access node can be provided by the server system 10, wherein the carbon emission footprint history includes but is not limited to carbon emissions directly or indirectly generated by a person, a transportation tool, etc.; recording a standard current price of the standard package 70, and storing the standard package 70 after transportation to The storage space is scanned by the tag to obtain the access node, and the storage time and the carbon emissions directly or indirectly generated are recorded and stored in the carbon data report; the recycled material in the standard package 70 is tested and judged to generate a purity grade of the recycled material, and recorded in the carbon data report of the access node; according to the purity grade and with reference to the standard current price, a first-level compensation is generated. ; Take multiple identical physical or chemical quantities of the standard packaging 70 of the recycled materials, reform them through a reprocessing process, mix them, and then re-manufacture them. At the same time, scan the code and record the carbon emissions of the reprocessing process in the carbon data report; divide all the carbon emission records of the carbon data report equally among the recycled finished products produced by the reprocessing process, and generate a finished product carbon emission record, a production history, and a carbon certificate for the recycled finished product.

From the above description, it can be seen that the present invention has the following characteristics:

1. Completely record the carbon footprint generated by the waste recycling process, systematically generate fair and open records, comply with the ISO spirit, contribute to the fairness and credibility of future carbon certificates, and completely solve the problems of existing technologies.

2. In the recycling process, monitoring and standard packaging can be cleverly used to effectively provide production history and carbon emission records at the same time as the output of recycled products, achieving the unexpected effect of intelligent carbon inventory and tracking records.

10:Servo system

20: Applications

30: Detection device

40: Warehouse management system

50: Image capture device

60: Barcode recognition device

70: Standard packaging

A: Mobile device

Claims (5)

A method for metal recycling and regeneration production history with carbon disclosure, the steps of which include: a system fills a recycled material into a standard package and scans a label of the standard package to obtain an access node of a carbon data report; the system records a detection result of a physical or chemical quantity of the recycled material, a real-time image of filling the recycled material into the standard package, a carbon emission footprint history and a factory recycling information at the access node; and the system records a standard current price of the standard package, and stores the standard package in a storage space after transportation, and scans the label to obtain the access node, records the time of the storage space and the carbon emissions directly or indirectly generated, and stores them in the carbon data report. The metal recycling and regeneration production history method with carbon disclosure as described in claim 1 includes the following steps: the system performs a test on the recycled material in the standard packaging to generate a purity level of the recycled material and records it in the carbon data report of the access node. The method for metal recovery and regeneration production with carbon disclosure as described in claim 2 includes the following steps: the system generates a first-level compensation based on the purity level and with reference to the standard current price. The metal recycling and regeneration production history method with carbon disclosure as described in claim 1, 2 or 3 includes the following steps: the system takes a plurality of the same physical or chemical quantities of the standard packaged recycled materials and reforms and mixes them through a reprocessing process, and at the same time scans and records the carbon emissions of the reprocessing process in the carbon data report. The method for metal recycling and regeneration production history with carbon disclosure as described in claim 4 includes the following steps: the system distributes all carbon emission records of the carbon data report to a recycled finished product produced by the reprocessing process, and generates a finished product carbon emission record, a production history and a carbon certificate for the recycled finished product.

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