CN110956006A - Design scheme of intelligent manufacturing line of graphene power battery - Google Patents
Design scheme of intelligent manufacturing line of graphene power battery Download PDFInfo
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- CN110956006A CN110956006A CN201911187541.9A CN201911187541A CN110956006A CN 110956006 A CN110956006 A CN 110956006A CN 201911187541 A CN201911187541 A CN 201911187541A CN 110956006 A CN110956006 A CN 110956006A
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Abstract
The application relates to a design scheme of an intelligent graphene power battery manufacturing line, which comprises the steps of completing the process flow, equipment, main parameters and main operation design of A, B module blocks of two lines in an intelligent manufacturing factory. The high-end equipment manufacturing method is characterized in that high-end equipment manufacturing which integrates mechanical, electrical, hydraulic, instrument, optical and artificial intelligence integrated technologies is superposed and applied to the integrated operation of information technology, networking (Internet and Internet of things), intelligent manufacturing, automation, artificial intelligence, digitalization, robots, manipulators and automatic transmission systems. The upgrading and spanning development of the resource utilization efficiency, the factory structure level, the informatization degree, the quality, the efficiency and the benefit are realized. Line A: cell manufacturing line, line B: the above related contents are applied to the battery module manufacturing line. The intelligent control systems A, B are all compatible with each other, and can replace and connect with each other to complete manufacturing and personalized services.
Description
Technical Field
The invention discloses a design scheme of an intelligent manufacturing line of a graphene power battery, which is completed by designing a process flow, equipment, main parameters and main actions of module blocks in an intelligent manufacturing factory. The manufacturing supply scheme is provided for meeting all individualized different customers, the integrated operation of a transmission system is realized by applying information technology, networking (Internet, Internet of things), automation, artificial intelligence, digitalization, robots, mechanical arms and the like, and the intelligent manufacturing of high-end equipment integrated by integrating six integrated technologies of mechanical, electrical, hydraulic, instrument, optical and artificial intelligence is superposed and applied. The upgrading and spanning development of the resource utilization efficiency, the factory structure level, the informatization degree, the quality, the efficiency and the benefit are realized. FIG. 1: line a (hereinafter referred to as line a): graphite alkene power battery electricity core intelligence manufacturing line, fig. 2: line B (hereinafter referred to as line B): the above related contents are applied to the battery module manufacturing line. Line A: the method comprises the following steps that (1) N process flows of module blocks in an intelligent factory are designed and completed corresponding to N devices, main parameters and main actions; the user personalized requirements are fulfilled. The method comprises the following steps of A line automatic production, cell manufacturing, battery formation and intelligent control system position design (a manufacturer is required to design a computer software copy for manufacturing separately). In application of information technology, networking, automation and artificial intelligenceThe intelligent robot and manipulator integrated automatic transmission system realizes intelligent manufacturing, and high-end equipment manufacturing with integration of six integrated technologies of mechanical, electrical, hydraulic, instrument, optical and artificial intelligence is superposed and applied. The intelligent control systems A, B are all compatible, interchangeable, interconnected, and employ information technology, networked, intelligent, automated, and automated drive trains (all symbolized in the figures). In A, B, the related equipment and selection station are integrated by applying two or more main parameters of equipment corresponding to the technological process and initiative. The main characteristic functions of the graphene materials meeting the specific characteristic requirements of the graphene power battery are subjected to standard application and multiple schemes, multiple performances and multiple matching modes of multiple internal metal materials are selected in a variable or changeable mode, N material varieties are set to correspond to N sets of intelligent weighing devices and N sets of intelligent powder weighing and feeding multi-pipeline conveyors, and N sets of solvents, guiding aids and adhesives are subjected to multi-pipeline intelligent weighing devices and automatic conveying; the method comprises the following steps: the characteristic flexible microporous dielectric film is added in the automatic sheet making combination of the line A1, and an automatic high-speed pulping system, an automatic feeding system, a transmission system and the like are all intelligentized and automated; line B: graphene power battery intelligent manufacturing line module: all six parts in the pack production line are integrated into one body, and the battery core is assembled to all modularized transmission systems and equipment and is designed by adopting the process flow, the equipment, the main parameters and the main action of module blocks in an intelligent factory. The pack line completes the complete manufacture of the battery module and the design of the intelligent control system location (requiring the manufacturer to design a computer software copy for additional manufacturing). The intelligent manufacturing is realized by applying information technology, networking, automation, artificial intelligence, digitalization, and robot and manipulator and automatic transmission system integrated operation, and high-end equipment manufacturing with integration of mechanical, electrical, hydraulic, instrument, optical and artificial intelligence six-bit integrated technology is superposed and applied. The intelligent control systems A, B are all compatible, replaceable, and interconnected. Under the condition of the failure of one control system A or B, the other production operation is not influenced or the respective single-line operation is carried out, and the other line or the other control system can be salvageed at the same time. In A, B two linesAll the selected stations (working sections) are integrated by applying two or more equipment main parameters corresponding to the process flows and actively performing the operation. A. The transmission connection mode, the unidirectional flow direction, the bidirectional flow direction circulation and the mutual compatibility of the two-wire design B are all represented by the symbol design in the diagram: → Do No. 2,And the like; all equipment and stations are additionally provided with sensors, scanners and the like, the process flow corresponds to all equipment and transmission systems, and meanwhile, the equipment system corresponds to the completion of main parameters and main operation: the method provides a mode, an operation flow, main manufacturing process program content and a general framework for the technical scheme of the manufacturing process of the graphene power battery with mechanical arm equipment plates under all intelligent control and the equipment scale economic volume production thereof, and provides new technical element conditions and implementation schemes for equipment design, complete set and automation or intelligent production for the graphene power battery manufacturing line for new equipment or modification on various original battery production lines. A complete set of equipment is provided for subsequent matched manufacturing equipment, and a design technical scheme is provided for subdividing the technological level of manufactured products. An economical technical approach is provided for promoting the large-scale mass production and the economy of the graphene power battery. And a powerful foundation support is laid for creating the large development of the industry. The A-line graphene battery cell equipment manufacturing line and the B-line graphene battery module line (pack line) equipment have already finished the design of the whole manufacturing line of the corresponding manufacturing equipment industrial factory as feasible technical solutions.
Background
According to the serious defects that the charging time of the current global lithium battery is too long, the electric conduction and heat dissipation performance is poor, the serious endurance is insufficient, the spontaneous combustion is caused, the self-explosion is caused when the battery meets water, the weight is heavy, the size is large, the serious pollution cannot be solved when the battery is disassembled, the requirements of mobile phones and notebook computers and all machines, land vehicles, ship aircraft carriers, aerospace and military equipment cannot be met, the requirements of all the industry fields cannot be met, the field operation application cannot be met, and the like, the graphene power battery expected in 21 century by human beings, and the process material and the product with the strong electric conduction and heat dissipation performance, the electricity storage capacity and the charging and discharging speed characteristic performance cannot be replaced. Under the lead rights of all scientists competing for large-scale economic and industrial speaking rights and economic technology large-scale production, equipment for producing the graphene power battery becomes the biggest world-level problem restricting the use of all human beings, and the invention can realize the large-scale economic volume production of the graphene power battery under the industrialization of large-scale economic volume production and intelligent manufacturing high-end equipment.
Disclosure of Invention
According to claim 1, the design is such that line a: fig. 1, line B: fig. 2 includes diagrams, which are technically characterized in that: the invention discloses a design scheme of an intelligent manufacturing line of a graphene power battery, which is completed by designing a process flow, equipment, main parameters and main actions of module blocks in an intelligent factory. The intelligent robot is manufactured by applying information technology, networking, automation, artificial intelligence, digitalization, robot and manipulator and automatic transmission system integrated operation, and high-end equipment manufactured by superposing and applying integration of mechanical, electrical, hydraulic, instrument, optical and artificial intelligence six-bit integrated technology. The upgrading and spanning development of the resource utilization efficiency, the factory structure level, the informatization degree, the quality, the efficiency and the benefit are realized. Line A: graphite alkene power battery electricity core intelligence manufacturing line, B line: the above related contents are applied to the battery module manufacturing line.
According to claim 1, the design is such that line a: FIG. 1, including various diagrams, is technically characterized in that: line A: the process flow, equipment, main parameters and main operation of the picture blocks in the intelligent factory are designed; the design of automatic production, cell production, battery formation and the position of an intelligent control system (a manufacturer is required to design a computer software copy for additional manufacture) is completed. The intelligent robot is manufactured by applying information technology, networking, automation, artificial intelligence, digitalization, robot and manipulator and automatic transmission system integrated operation, and high-end equipment manufactured by superposing and applying integration of mechanical, electrical, hydraulic, instrument, optical and artificial intelligence six-bit integrated technology. The intelligent control systems A, B are all compatible, mutually replaced and connected, and all adopt information technology, networking, intellectualization and automationAnd automated transmission systems (both symbolized in the figures). In A, B, the relevant equipment and station, and part of the stations are selected and integrated by applying the main parameters of the equipment corresponding to two or more technological processes. A. The transmission connection mode, the unidirectional flow direction, the bidirectional flow direction circulation and the mutual compatibility of the two-wire design B are all represented by the symbol design in the diagram: → Do No. 2, And the like; all equipment and stations are additionally provided with sensors, scanners and the like, the process flow corresponds to all equipment and transmission systems, and meanwhile, the equipment system corresponds to the completion of main parameters and main operation. The main characteristic functions of the graphene materials meeting the specific characteristic requirements of the graphene power battery are subjected to standard application and multiple schemes, multiple performances and multiple matching modes of multiple internal metal materials are selected in a variable or changeable mode, the multiple internal metal materials are designed to be set into N material varieties which correspond to N sets of intelligent weighing machines for automatic conveying, N sets of powder feeding multi-pipeline conveyors, and N sets of solvents, guiding aids and adhesives are automatically conveyed by the multi-pipeline intelligent weighing machines; the method comprises the following steps: the characteristic flexible microporous dielectric film is added in the automatic sheet making combination of the line A1, and an automatic high-speed pulping system, an automatic feeding system, a transmission system and the like are all intelligentized and automated. N in turn represents an added or subtracted personalization of all equipment and process flows. Different grades of requirements and different technical and economic index requirements under cost differentiation and demand differentiation are adopted, and the grades of the selected characteristic graphene nano materials are respectively as follows: 1-3nm, 4-10nm, 11-20nm and the like.
According to claim 1, the line B in the design: FIG. 2, including the various diagrams, is technically characterized in that: line B: graphene power battery intelligent manufacturing line module: all six parts in the pack production line are integrated and intelligentized, and the battery cell is assembled to all modularized transmission systems and equipment by adopting the process flow, equipment, main parameters and the like of picture blocks in an intelligent factory,The main operation design is finished. The pack line completes the complete manufacturing of the battery module, completes the design of the intelligent control system position (a computer software copy is designed by a manufacturer and is configured additionally). The intelligent robot is manufactured by applying information technology, networking, automation, artificial intelligence, digitalization, robot and manipulator and automatic transmission system integrated operation, and high-end equipment manufactured by superposing and applying integration of mechanical, electrical, hydraulic, instrument, optical and artificial intelligence six-bit integrated technology. The intelligent control systems A, B are all compatible, replaceable, and interconnected. And A, B, two or more equipment main parameters corresponding to the process flows are applied in the two lines, and the main operation is completed to be integrated. A. The transmission connection mode, the unidirectional flow direction, the bidirectional flow direction circulation and the mutual compatibility of the two-wire design B are all represented by the symbol design in the diagram: → Do No. 2, And the like; all equipment and stations are additionally provided with sensors, scanners and the like, the process flow corresponds to all equipment and transmission systems, and meanwhile, the equipment system corresponds to the completion of main parameters and main operation. The method realizes economy, rapidness, convenience, integration and conservation, and meets all different customer requirements.
According to claim 1, the technical characteristics of the design scheme are as shown in fig. 1 and fig. 2: the intelligent control systems A, B are all compatible, replaceable, and interconnected. And A, B, two or more equipment main parameters corresponding to the process flows are applied to the selected stations in two lines, and the equipment main parameters and the active operation are integrated into a whole, so that the efficiency of each equipment can be adjusted according to the required capacity. A. The transmission connection mode, the unidirectional flow direction, the bidirectional flow direction circulation and the mutual compatibility of the two-wire design B are all represented by the symbol design in the diagram: → Do No. 2,And the like; the process flow corresponds toAll equipment and transmission systems, and the equipment system corresponds to the completion of main parameters and main actions: the method provides a mode, an operation flow, main manufacturing process program content and a general architecture for the manufacturing process technical scheme of the graphene power battery for the mechanical arm equipment plate under all intelligent control and the equipment scale economic volume production thereof, provides equipment design, complete set and automation or intelligent production for new equipment or modification on various original battery production lines, provides a scheme for various personalized users, and provides a traceable scheme for all material sources and product user backup. A complete set of equipment is provided for subsequent matched manufacturing equipment, and a design technical scheme is provided for subdividing the technological level of manufactured products. All N are different requirements for designing economic and technical indexes of independently selecting equipment processes. An economical technical approach is provided for promoting the large-scale economical mass production of the graphene power battery. And a powerful foundation support is laid for creating the large development of the industry. The production operation process flow chart of the graphene battery product equipment manufacturing line and the block of the graphene battery modular equipment production manufacturing process flow module have already finished the main parameters of the corresponding manufacturing equipment, and the design of the industrial factory manufacturing line under the condition of finishing the main operation is a feasible technical scheme. The equipment design adopts instruments, meters, photoelectricity, scanning and the like which all select precise levels. Selection of automatic transmission system: and respectively selecting transmission mechanisms according to the product model, the dimension, the size and the weight.
According to claim 1, the technical characteristics of the design scheme are as shown in fig. 1 and fig. 2: the intelligent information technology applies all intelligent integrated functions of big data collection, analysis, modeling, self-learning, self-recovery, self-recognition, self-processing and the like, and is designed in an intelligent control system (another computer software is required to be developed) for field management, remote management, organization and personnel management, logistics management and the like. The mobile phone management and application of the mobile terminal and the computer management and application of the PC terminal are applied to two aspects, namely an equipment scheme module and a general structure, and a modern management means related to information technology application is provided for computer software design and development.
According to claim 1, the technical characteristics of the design scheme are as shown in fig. 1 and fig. 2: selection of power and automatic transmission system: and respectively selecting a transmission mode and a mechanism according to the product model, the dimension, the size and the weight. Power selection: electric, pneumatic, linkage, hydraulic, etc.
According to claim 1, the technical characteristics of the design scheme are as shown in fig. 1 and fig. 2: the mobile phone management and application of the mobile terminal and the computer management of the PC terminal are applied to two aspects, namely an equipment scheme module and a general structure, and a management means related to modern information technology is provided for computer software design.
The design scheme as claimed in claim 1, wherein the structural formula is as follows: the line A is a battery cell manufacturing line. The line A and the line B are completed by an integral production line of a battery core manufacturing line and a battery module assembling manufacturing line. Integration: the A line has 48 modules, and the B line has 21 modules, which are all designed with variability selectivity.
The design according to claim 1, wherein the attached figure 2: the B line is a battery module assembly manufacturing line (pack line). The line A and the line B are completed by an integral production line of a battery core manufacturing line and a battery module assembling manufacturing line.
According to claim 1, the technical characteristics of the design scheme are as shown in fig. 1 and fig. 2: the production environment conditions are as follows: above 18 ℃, below 28 ℃, electric power: 50HZ, 380V, 220V, 5V3A, … …. Energy conservation, emission reduction, environmental protection, dust prevention, fire prevention, health, safety and the like all execute national standards, enterprise and industry standards and ISO series certification.
According to claim 1, the technical characteristics of the design scheme are as shown in fig. 1 and fig. 2: the graphene power battery, including the graphene battery, adopts the same manufacturing approach, process flow and equipment technical main parameters, and is applied to the industries, industries and fields as follows: all machines (including mobile phones, tablet computers, electrical appliances, machines, communication and other application types), land vehicles, ship aircraft carriers, aerospace and military equipment are classified into five major industrial applications (namely, the inventor creates and creates a new name in the related copyright of the multi-book). Pack: processing, assembling, packaging, detecting and the like, and customizing and manufacturing services for different types and specifications required by different customers. Attached: fig. 1 and 2.
Drawings
FIG. 1: line A: the intelligent manufacturing line equipment for the graphene power battery cell corresponds to production operation process flows, main parameters and actions.
FIG. 2: line B: graphene power battery intelligent manufacturing line module: the pack production line equipment corresponds to the production operation process flow, main parameters and actions.
Claims (11)
1. The invention discloses a design scheme of an intelligent manufacturing line of a graphene power battery, which is completed by designing a process flow, equipment, main parameters and main actions of module blocks in an intelligent manufacturing factory. The manufacturing supply scheme is provided for meeting all individualized different customers, the integrated operation of a transmission system is realized by applying information technology, networking (Internet, Internet of things), automation, artificial intelligence, digitalization, robots, mechanical arms and the like, and intelligent manufacturing of high-end equipment by using a mechanical-electrical-hydraulic-instrument-optical-artificial-intelligence six-bit integrated technology is superposed. The upgrading and spanning development of the resource utilization efficiency, the factory structure level, the informatization degree, the quality, the efficiency and the benefit are realized. FIG. 1: line a (hereinafter referred to as line a): graphite alkene power battery electricity core intelligence manufacturing line, fig. 2: line B (hereinafter referred to as line B): the above related contents are applied to the battery module manufacturing line. Line A: the method comprises the following steps that (1) N process flows of module blocks in an intelligent factory are designed and completed corresponding to N devices, main parameters and main actions; the user personalized requirements are fulfilled. The method comprises the following steps of A line automatic production, cell manufacturing, battery formation and intelligent control system position design (a manufacturer is required to design a computer software copy for manufacturing separately). The intelligent manufacturing is realized by applying information technology, networking, automation, artificial intelligence, digitalization, and robot and manipulator and automatic transmission system integrated operation, and high-end equipment manufacturing with integration of mechanical, electrical, hydraulic, instrument, optical and artificial intelligence six-bit integrated integration technology is superposed and applied. The intelligent control systems A, B can be compatible with each other, replaced with each other, connected with each other, and adoptedInformation technology, networking, intelligence, automation, and automation drive systems (all symbolized in the figures). In A, B, the related equipment and selection station are integrated by applying two or more main parameters of equipment corresponding to the technological process and initiative. The main characteristic functions of the graphene materials meeting the specific characteristic requirements of the graphene power battery are subjected to standard application and multiple schemes, multiple performances and multiple matching modes of multiple internal metal materials are selected in a variable or changeable mode, N material varieties are set to correspond to N sets of intelligent weighing devices and N sets of intelligent powder weighing and feeding multi-pipeline conveyors, and N sets of solvents, guiding aids and adhesives are subjected to multi-pipeline intelligent weighing devices and automatic conveying; the method comprises the following steps: the characteristic flexible microporous dielectric film is added in the automatic sheet making combination of the line A1, and an automatic high-speed pulping system, an automatic feeding system, a transmission system and the like are all intelligentized and automated; line B: graphene power battery intelligent manufacturing line module: all six parts in the pack production line are integrated into one body, and the battery core is assembled to all modularized transmission systems and equipment and is designed and completed by adopting block process flow, equipment, main parameters and main action in an intelligent factory. The pack line completes the complete manufacture of the battery module and the design of the intelligent control system location (requiring the manufacturer to design a computer software copy for additional manufacturing). The intelligent manufacturing is realized by applying information technology, networking, automation, artificial intelligence, digitalization, and integrated operation of a robot, a manipulator and an automatic transmission system, and high-end equipment manufacturing with integration of mechanical, electrical, hydraulic, instrument, optical and artificial intelligence six-bit integrated technology is superposed and applied. The intelligent control systems A, B are all compatible, replaceable, and interconnected. And under the failure of one control system A or B, the other production operation is not influenced or the respective single-line operation is carried out, and the other line or the other control system is salvageed. In A, B, two or more stations (sections) are selected, and integrated by applying two or more equipment main parameters corresponding to the technological process and initiative. A. The transmission connection mode, the unidirectional flow direction, the bidirectional flow direction circulation and the mutual compatibility of the two-wire design B are all represented by the symbol design in the diagram: → Do No. 2,And the like; all equipment and stations are additionally provided with sensors, scanners and the like, the process flow corresponds to all equipment and transmission systems, and meanwhile, the equipment system corresponds to the completion of main parameters and main operation: the method provides a mode, an operation flow, main manufacturing process program content and a general framework for the technical scheme of the manufacturing process of the graphene power battery with mechanical arm equipment plates under all intelligent control and the equipment scale economic volume production thereof, and provides new technical element conditions and implementation schemes for equipment design, complete set and automation or intelligent production for the graphene power battery manufacturing line for new equipment or modification on various original battery production lines. A complete set of equipment is provided for subsequent matched manufacturing equipment, and a design technical scheme is provided for subdividing the technological level of manufactured products. An economical technical approach is provided for promoting the large-scale mass production and the economy of the graphene power battery. And a powerful foundation support is laid for creating the large development of the industry. The A-line graphene battery cell equipment manufacturing line and the B-line graphene battery module line (pack line) equipment have already finished the design of the whole manufacturing line of the corresponding manufacturing equipment industrial factory as feasible technical solutions.
2. According to claim 1, the design is such that line a: fig. 1, line B: fig. 2 includes diagrams, which are technically characterized in that: the invention discloses a design scheme of an intelligent manufacturing line of a graphene power battery, which is completed by designing process flows, equipment, main parameters and main actions of blocks in an intelligent factory. The intelligent robot is manufactured by applying information technology, networking, automation, artificial intelligence, digitalization, robot and manipulator and automatic transmission system integrated operation, and high-end equipment manufactured by superposing and applying integration of mechanical, electrical, hydraulic, instrument, optical and artificial intelligence six-bit integrated technology. The upgrading and spanning development of the resource utilization efficiency, the factory structure level, the informatization degree, the quality, the efficiency and the benefit are realized. Line A: graphite alkene power battery electricity core intelligence manufacturing line, B line: the above related contents are applied to the battery module manufacturing line.
3. According to claim 1, the design is such that line a: FIG. 1, including various diagrams, is technically characterized in that: line A: the process flow, equipment, main parameters and main operation of the picture blocks in the intelligent factory are designed; the design of automatic production, cell production, battery formation and the position of an intelligent control system (a manufacturer is required to design a computer software copy for additional manufacture) is completed. The robot and the mechanical arm are manufactured intelligently by the integrated operation of the information technology, networking, automation, artificial intelligence, digitalization and robot and mechanical arm and automatic transmission system, and the high-end equipment is manufactured by the integrated technology of six positions of mechanical, electrical, hydraulic, instrument, optical and artificial intelligence.
4. The design of claim 1, wherein line A, B: the technical characteristics are as follows: the intelligent control systems A, B are all compatible, interchangeable, interconnected, and employ information technology, networked, intelligent, automated, and automated drive trains (all symbolized in the figures). In A, B, the relevant equipment and station, and part of the stations are selected and integrated by applying the main parameters of the equipment corresponding to two or more technological processes. A. The transmission connection mode, the unidirectional flow direction, the bidirectional flow direction circulation and the mutual compatibility of the two-wire design B are all represented by the symbol design in the diagram: → Do No. 2,And the like; all equipment and stations are additionally provided with sensors, scanners and the like, the process flow corresponds to all equipment and transmission systems, and meanwhile, the equipment system corresponds to the completion of main parameters and main operation.
5. According to claim 1, the design is such that line a: the technical characteristics are as follows: the main characteristic functions of the graphene materials meeting the specific characteristic requirements of the graphene power battery are subjected to standard application and multiple schemes, multiple performances and multiple matching modes of multiple internal metal materials are selected in a variable or changeable mode, the multiple internal metal materials are designed to be set into N material varieties which correspond to N sets of intelligent weighing machines for automatic conveying, N sets of powder feeding multi-pipeline conveyors, and N sets of solvents, guiding aids and adhesives are automatically conveyed by the multi-pipeline intelligent weighing machines; the method comprises the following steps: the characteristic flexible microporous dielectric film is added in the automatic sheet making combination of the line A1, and an automatic high-speed pulping system, an automatic feeding system, a transmission system and the like are all intelligentized and automated. N in turn represents an added or subtracted personalization of all equipment and process flows. Different grades of requirements and different technical and economic index requirements under cost differentiation and demand differentiation are adopted, and the grades of the selected characteristic graphene nano materials are respectively as follows: 1-3nm, 4-10nm, 11-20nm and the like.
6. According to claim 1, the line B in the design: FIG. 2, including the various diagrams, is technically characterized in that: line B: graphene power battery intelligent manufacturing line module: all six parts in the pack production line are manufactured in an integrated intelligent mode, and the battery core is assembled to all modularized transmission systems and equipment and is designed and completed by adopting block process flows, equipment, main parameters and main actions in an intelligent factory. The pack line completes the complete manufacturing of the battery module, completes the design of the intelligent control system location (requires the manufacturer to design a computer software copy for additional manufacturing). The intelligent robot is manufactured by applying information technology, networking, automation, artificial intelligence, digitalization, robot and manipulator and automatic transmission system integrated operation, and high-end equipment manufactured by superposing and applying integration of mechanical, electrical, hydraulic, instrument, optical and artificial intelligence six-bit integrated technology. The intelligent control systems A, B are all compatible, replaceable, and interconnected. And A, B, two or more equipment main parameters corresponding to the process flows are applied in the two lines, and the main operation is completed to be integrated. A. The transmission connection mode, the unidirectional flow direction, the bidirectional flow direction circulation and the mutual compatibility of the two-wire design B are all represented by the symbol design in the diagram: → Do No. 2, And the like; all equipment and stations are additionally provided with sensors, scanners and the like, the process flow corresponds to all equipment and transmission systems, and meanwhile, the equipment system corresponds to the completion of main parameters and main operation. The method realizes economy, rapidness, convenience, integration and conservation, and meets all different customer requirements.
7. According to claim 1, the technical characteristics of the design scheme are as shown in fig. 1 and fig. 2: the intelligent control systems A, B are all compatible, replaceable, and interconnected. And A, B, selecting two or more equipment main parameters corresponding to the process flows at the station, and actively manufacturing the equipment to form integrated equipment, wherein the equipment efficiency can be adjusted according to the required capacity. The composition integration is as follows: the A line has 48 modules, and the B line has 21 modules, which are all designed with variability selectivity. A. The transmission connection mode, the unidirectional flow direction, the bidirectional flow direction circulation and the mutual compatibility of the two-wire design B are all represented by the symbol design in the diagram: → Do No. 2,And the like; the process flow corresponds to all equipment and transmission systems, and the equipment system corresponds to the completion of main parameters and main actions: the method provides a mode, an operation flow, main manufacturing process program content and a general architecture for the manufacturing process technical scheme of the graphene power battery for the mechanical arm equipment plate under all intelligent control and the equipment scale economic volume production thereof, provides equipment design, complete set and automation or intelligent production for new equipment or modification on various original battery production lines, provides a scheme for various personalized users, and provides a traceable scheme for all material sources and product user backup. A complete set of equipment is provided for subsequent matched manufacturing equipment, and a design technical scheme is provided for subdividing the technological level of manufactured products. All N are design-independentSelecting different requirements of economic and technical indexes of equipment processes. An economical technical approach is provided for promoting the large-scale economical mass production of the graphene power battery. And a powerful foundation support is laid for creating the large development of the industry. The production operation process flow chart of the graphene battery product equipment manufacturing line and the production manufacturing process flow chart of the graphene battery modular equipment have already finished the technical scheme corresponding to the design of the manufacturing line of the manufacturing equipment industrial factory as feasibility.
8. According to claim 1, the technical characteristics of the design scheme are as shown in fig. 1 and fig. 2: the equipment design adopts instruments, meters, photoelectricity, scanning and the like which all select precise levels. Selection of automatic transmission system: and respectively selecting transmission mechanisms according to the product model, the dimension, the size and the weight.
9. According to claim 1, the technical characteristics of the design scheme are as shown in fig. 1 and fig. 2: the intelligent information technology applies all intelligent integrated functions of big data collection, analysis, modeling, self-learning, self-recovery, self-recognition, self-processing and the like, and carries out field management, remote management, organization and personnel management, logistics management and the like which are all designed in an intelligent control system (another computer software copy configuration needs to be developed). The mobile phone management and application of the mobile terminal and the computer management of the PC terminal are applied to two aspects, namely an equipment scheme module and a general structure, and a modern management means related to information technology application is provided for computer software design.
10. According to claim 1, the technical characteristics of the design scheme are as shown in fig. 1 and fig. 2: the production environment conditions are as follows: above 18 ℃, below 28 ℃, electric power: 50HZ, 380V, 220V, 5V3A, … …. Energy conservation, emission reduction, environmental protection, dust prevention, fire prevention, health, safety and the like all execute national standards, industrial standards and ISO series certification.
11. According to claim 1, the technical characteristics of the design scheme are as shown in fig. 1 and fig. 2: the graphene power battery, including the graphene battery, adopts the same manufacturing approach, process flow and equipment technical main parameters, and is applied to the industries, industries and fields as follows: all machines (including mobile phones, tablet computers, electrical appliances, machines, communication and other application types), land vehicles, ship aircraft carriers, aerospace and military equipment are classified into five major industrial applications (namely, the inventor creates and creates a new name in the related copyright of the multi-book). Pack: processing, assembling, packaging, detecting and the like, and customizing and manufacturing services for different types and specifications required by different customers. Attached: fig. 1 and 2.
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