Process Equipment and Control Engineering

Engineering Drawing A

This course is based on the orthographic projection method and focuses on the principles of projecting points, lines, and surfaces, as well as the techniques for representing intersection lines and tangent lines. It investigates the common representation methods for various mechanical components in engineering. As a core course in the training of personnel in the field of mechanical engineering, this course aims to develop students' spatial imagination, drawing skills, drafting abilities using scales, and computer-aided design (CAD) capabilities. It serves as a fundamental basis for subsequent studies in engineering-related disciplines. Through the study of this course, students majoring in mechanical engineering will acquire the ability to visually represent common mechanical components, locomotives, process equipment, etc. They will also develop the skills to interpret relevant engineering drawings. This course plays a crucial role in laying the groundwork for students to engage in more advanced studies within the field of engineering.

 

Fundamentals of Electrical and Electronic Engineering

This course is an important theoretical and practical technical foundation course in non-electrical majors at higher education institutions. With extensive content, it covers multiple foundational subjects in electrical engineering such as circuit theory, electronic technology, motor control, and instrumentation. This course itself holds strong practicality and applicability. Given the widespread and rapid development of electrical and electronic technologies today, this course plays a crucial role in enhancing students' abilities in applying electrical and electronic technology.

 

Mechanical Engineering Materials A

This course serves as a foundational subject for mechanical and related majors. Its focus lies in the study of the relationship between the properties, composition, structure, and heat treatment of metallic materials. Through this course, students gain fundamental knowledge of mechanical engineering materials, developing essential skills in selecting and applying common heat treatment methods, processing techniques, material testing, and basic abilities in theoretical analysis, problem-solving, and comparing engineering solutions while considering environmental impact factors. It lays necessary groundwork for subsequent specialized courses.

 

Material Mechanics

This course is a foundational core course for Process Equipment and Control Engineering, offering theoretical and computational methods for process equipment design and manufacturing. It addresses the strength, stiffness, and stability issues of engineering force components, determining the safe working conditions of these components. Through this course, students acquire the ability to identify and assess common mechanical problems in engineering, as well as to create simple mechanical models and conduct problem-solving and calculations.

 

Principle of Chemical Engineering B

This course is a technical foundation course for Chemical Engineering, Process Equipment and Control, and related majors. It serves as a bridge between foundational and specialized courses, integrating mathematical, physical, and chemical knowledge to analyze and solve various unit operation problems in chemical processes. Comprehensive training covers fundamental theory, equipment construction, design methods, engineering operations, and experimental organization. Emphasizing an engineering perspective and the integration of theory and practice, this course plays a crucial role in shaping an engineering mindset and enhancing students' abilities to analyze and solve practical problems.

 

Process Fluid Machinery

This course is a highly practical and applied core course that extensively and systematically introduces commonly used fluid machinery in process industries such as blade pumps, compressors, and centrifuges. Its main objective is to equip students with a systematic understanding of the basic requirements, design concepts, classifications, and applications of process fluid machinery. It aims to provide fundamental engineering knowledge, enabling students to preliminarily select or design commonly used fluid machinery and develop the ability to solve complex engineering problems in the process industry by integrating various knowledge domains.

 

Process Equipment Control Technology and Application

This course is a core professional subject that mainly covers control technology basics, common process parameter detection techniques, process control devices, and computer control systems. Through theoretical learning and experimental operations, students grasp fundamental knowledge of industrial process instrumentation and control. They gain an understanding of the history and development trends of industrial process instrumentation and control, laying a theoretical foundation for the design, analysis, and evaluation of process equipment control systems, which will be essential for addressing control-related issues in future production, equipment design, development, and scientific research.

 

Process Equipment Design

This course comprehensively and systematically elaborates on the basic structure and design requirements of pressure vessels. It also encompasses policies, guidelines, regulations, and laws related to the design, production, research, development, environmental protection, and sustainable development within the relevant professions and industries. Combining professional techniques with ideological and political education, the course demands that students master the basic methods of pressure vessel design with professional ethics, craftsmanship spirit, and engineering ethics. Students become familiar with the application and structure of common process equipment, establish preliminary complete ideas for process equipment design, cultivate their ability to solve complex engineering problems, and instill a sense of patriotism, idealism, and the spirit of craftsmanship for the nation's prosperity.

 

Complete Set of Process Equipment Technology

This course is a compulsory core subject, covering major technical issues involved in the entire process from product development to device commissioning in process industries. It encompasses aspects such as technology, equipment, electrical aspects, instrumentation, finance, construction, piping, HVAC, and corrosion prevention, extending up to installation and commissioning. Through this course, students majoring in Process Control gain essential knowledge and methods for senior engineering and technical management roles, empowering them to address complex engineering problems in the process industry by integrating diverse knowledge.

 

Process Equipment Manufacturing and Testing

This course is a core subject focusing on the processing methods of various components of process equipment, commonly used processing equipment, assembly techniques, relevant quality control standards, and the specific implementation processes. By studying this course, students gain the capability to design manufacturing processes and assembly techniques for various components of process equipment and fluid machinery. They develop the ability to handle the conflicts between manufacturing and design scientifically, along with the competence to solve complex engineering problems by integrating diverse knowledge in the field of process industries.

 

Mechanical Design, Manufacturing, and Automation 

Engineering Drawing A

The course is based on the principles of orthographic projection, utilizing the projection rules for points, lines, and surfaces, as well as techniques for drawing intersecting and tangential lines. It focuses on studying common representation methods for various mechanical components in engineering. This course is a core subject in the education of talents in the field of mechanical engineering, aiming to cultivate students' spatial imagination, drawing skills, dimensioning and drafting abilities, and proficiency in computer-aided design (CAD). It serves as a foundation for subsequent studies in engineering disciplines. Through this course, students in mechanical engineering gain the ability to illustrate common mechanical components, locomotives, process equipment, etc., and develop skills to interpret relevant engineering drawings.

 

Fundamentals of Electrical and Electronic Engineering

This course is crucial for non-electrical majors in higher education, emphasizing both theory and practical application. Its extensive content covers topics found in multiple foundational courses for electrical majors, such as circuit theory, electronic technology, electrical machines and control, and instrumentation. The course itself is highly practical and relevant, given the widespread and rapid development of electrical and electronic technologies today, playing a key role in enhancing students' capabilities in applying electrical and electronic technology. 

 

Mechanical Engineering Materials A

As a foundational course for mechanical and related majors, the course primarily focuses on the relationship between the properties, composition, structure, and heat treatment of metallic materials. Through this course, students acquire fundamental knowledge of materials in mechanical engineering, developing basic skills in selecting and applying common heat treatment methods, processing techniques, and material testing. This knowledge enables students to analyze, solve, and compare engineering solutions based on fundamental theories while considering environmental factors, thus laying the necessary groundwork for subsequent specialized courses.

 

Material Mechanics

As a foundational core course for the Process Equipment and Control Engineering major, this course provides theoretical and computational methods for the design and manufacturing of process equipment. It addresses the strength, stiffness, and stability issues of engineering force-bearing components, determining the conditions for their safe operation. The course aims to equip students with the ability to identify and assess common mechanical problems in engineering, as well as to establish simple mechanics models and solve and calculate solutions.

 

Machine Design

The course primarily investigates the working principles, structural characteristics, basic design theories, and design calculation methods of general mechanical components within common working conditions and parameter ranges. It also covers the design and selection of mechanical system solutions. Through this course, students in mechanical engineering gain knowledge in the design and analysis of various mechanical parts, proficiency in referencing technical materials and experimenting with common mechanical components, enabling them to design mechanical transmission devices and general machinery.

Mechanical Principle

This course is a crucial technical foundation for mechanical majors in higher education, teaching fundamental methods for analyzing the structure, motion, and force of various mechanisms, as well as the design and synthesis of commonly used mechanisms. Through this course, students acquire the ability to design, analyze, and synthesize various common planar mechanisms, solving practical engineering problems, and developing basic skills in referencing technical materials and using general instruments.

 

Automatic Control Principle

With a strong focus on theory and engineering applications, this course emphasizes the theoretical aspects while closely integrating content with practical engineering scenarios. It is a foundational course that utilizes classical control theory to study the dynamic problems of generalized systems in mechanical engineering. The course aims to shift students' perspective from a static to a dynamic viewpoint when assessing mechanical engineering systems. Students learn to analyze the dynamic behavior of a system by considering the transmission, conversion, and feedback of information within the entire system. Specific content includes understanding the basic structure, classification, and requirements of control systems; mastering control system modeling methods; understanding time-domain and frequency-domain analysis methods for linear time-invariant systems; analyzing the steady-state and transient characteristics of systems; understanding stability conditions and calibration methods for linear time-invariant systems.

 

Fundamentals of Interchangeability and Measurement

Grounded in the latest national and international standards, this course elaborates on mechanical precision design based on the theoretical knowledge system of the discipline. It also introduces error detection theory and methods in conjunction with detection specifications, emphasizing the cultivation of students' theoretical knowledge and applied abilities in mechanical precision design and detection technology. The goal is to enable students to identify, design, and correctly annotate the precision technical requirements of parts and assemblies using foundational knowledge in mechanical precision design. Additionally, students gain an understanding of the working principles and methods of precision detection instruments, allowing them to choose appropriate detection methods and measuring instruments for precision requirements in mechanical drawings. The course also covers the correct collection, processing, and analysis of experimental data to determine mechanical precision values and judge the acceptability of components.

 

Fundamentals of Material Forming Technology

This course serves as a foundational course for the Mechanical Design, Manufacturing, and Automation major, focusing on the basic principles and methods of material forming technology. Through this course, students acquire fundamental knowledge in material forming technology, enabling them to analyze influencing factors during the product forming process through literature research and data retrieval. Students learn to apply the basic theories of material forming to establish goals and plans for forming technology based on the shape, structure, dimensions, and practical production conditions of a product. They also develop the ability to analyze and demonstrate the feasibility of forming technology solutions considering factors such as social, health, safety, legal, cultural, and environmental considerations, laying a necessary foundation for subsequent specialized courses.

 

Mechanical & Electrical Transmission Control

This course, following courses such as Electrical and Electronic Fundamentals, Digital Electronic Technology, and Analog Electronic Technology, focuses on the control of electromechanical drives with a primary emphasis on machine tool electrical control. The course explains the working principles of electric motors and their mechanical characteristics, the basic principles of machine tool electrical control systems, practical machine tool electrical control circuits, the design methods of machine tool control circuits, and the basic principles and design methods of programmable logic controllers (PLC). Through this course, students in mechanical engineering develop the ability to design, analyze, and comprehensively apply various common electromechanical control systems, as well as possess the basic skills to solve real engineering problems.

 

Fundamentals of Mechanical Manufacturing Technology A

This compulsory course for the Mechanical Design, Manufacturing, and Automation major primarily investigates metal cutting principles, machine tools, fixtures, mechanical processing quality, and the design of machining process regulations. Through this course, students in the Mechanical Design and Automation major acquire knowledge of the principles, methods, and equipment of metal cutting processes, as well as the ability to design machining process technology and fixtures, and control the quality of mechanical processing.

 

Mechanical and Electronic Engineering

Engineering Drawing A

This course is based on the orthographic projection method, focusing on the projection principles of points, lines, and surfaces, as well as the drawing methods of intersecting and tangent lines. It explores common representation methods for various mechanical components in engineering. This course, a core course for mechanical engineering-related disciplines, aims to cultivate students' spatial imagination, drawing ability, drafting skills, and computer-aided design (CAD) proficiency. It serves as a foundation for subsequent studies in engineering disciplines. Through this course, mechanical engineering students will develop graphical skills for interpreting common mechanical components, locomotives, process equipment, etc., and gain the ability to read relevant engineering drawings.

 

High-level language programming

The course is highly practical, requiring a grasp of concepts, hands-on programming, and debugging on computers. It is also a major language in the national computer proficiency examination. The teaching goals of this course are to enable students to master various aspects of the C language, understand the basics of program design and techniques, possess initial advanced language programming skills, proficiently use C language programming environments for coding, compiling, and debugging, and develop the ability to apply C language to solve engineering problems. It lays the foundation for utilizing computer technology in process simulation and design.

 

Theoretical Mechanics

This course is a foundational theoretical subject and a scientific basis for modern engineering technology. Building on basic physics mechanics, it applies advanced mathematical tools to comprehensively and systematically expound the fundamental concepts and laws of macroscopic mechanical motion. The goal is to provide students with a complete understanding of the basic content of mechanics, the ability to handle mechanical problems, and enhance their theoretical analysis and abstract thinking skills. This solid foundation prepares them for further study in subjects like mechanical foundations and material mechanics.

 

Machine Design

The course primarily explores the working principles, structural characteristics, basic design theories, and design calculation methods of general mechanical components under typical working conditions and within common parameter ranges. It covers the design and selection of mechanical system solutions. The teaching aims to equip students with knowledge in the design and analysis of various mechanical parts, the ability to consult technical data using standard specifications, and expertise in experimenting with common mechanical components. Students should be capable of designing mechanical transmission devices and general machinery.

 

Mechanical Principle

As a crucial technical foundation course for mechanical engineering majors in higher education institutions, this course teaches the basic methods of analyzing the structure, motion, and force of various mechanisms, as well as the design and synthesis of commonly used mechanisms. Through this course, students acquire the ability to design, analyze, and synthesize common planar mechanisms, solve practical engineering problems, and use general instruments.

 

Automatic Control Principle

The course is highly theoretical and applicable in engineering. It is based on classical control theory, investigating the dynamic issues of generalized systems in mechanical engineering. The objective is to train students to view a mechanical engineering system from a dynamic perspective, analyze dynamic behavior through information transmission, transformation, and feedback in the entire system, and apply basic concepts and methods of classical control theory to analyze, research, and solve problems in engineering practice. Specific content includes understanding the basic structure, classification, and requirements of control systems; mastering control system modeling methods; understanding time-domain and frequency-domain analysis methods for linear time-invariant systems; analyzing the steady-state and transient characteristics of systems; understanding system stability conditions and calibration methods for linear time-invariant systems.

Fundamentals of Interchangeability and Measurement

Based on the latest national and international standards, this course discusses the design of mechanical accuracy using theoretical foundations and introduces error detection theory and methods through detection specifications. It emphasizes cultivating students' foundational theoretical knowledge and applied skills in mechanical accuracy design and detection technology. The goal is to enable students to identify, design, and correctly annotate the precision technical requirements of parts and assemblies using the basic knowledge of mechanical accuracy design. Students should understand the working principles and methods of mechanical accuracy testing instruments, choose appropriate testing methods and measuring instruments for precision requirements in mechanical drawings, and correctly collect, process, analyze experimental data to determine the mechanical accuracy, and judge the part’s acceptability.

 

Fundamentals of Mechanical Manufacturing Technology B

The course primarily covers metal cutting principles, machine tool design, and methods of metal processing technology and fixture design. It aims to provide students with a basic understanding of the fundamental manufacturing methods for metal parts and develop their ability to perform process analysis and design.

 

Mechanical & Electrical Transmission Control

This course, a fundamental course for mechanical design, manufacturing, and automation majors, follows courses in electrical engineering basics, digital electronics, and analog electronics. It focuses on electromechanical drive control with an emphasis on machine tool electrical control. The course explains the working principles of electric motors and mechanical characteristics, basic principles of machine tool electrical control systems, actual machine tool electrical control circuits, design methods for machine tool control circuits, and the basic principles and design methods of programmable logic controllers (PLC). Through this course, students gain the ability to design, analyze, and comprehensively apply various common electromechanical control systems and develop the basic skills to solve practical engineering problems.

 

Industrial Design

Engineering Drawing B

This course systematically presents the fundamental knowledge, principles, and methods of technical drawing, including basic body projections, projections of intersecting lines in 3D space, assemblies, common representation methods for objects, standard parts and components, part drawings, assembly drawings, and computer-aided drawing. It is a fundamental course for students in engineering disciplines, serving as an important tool for solving positioning, measurement, calculation, design, and conceptualization problems in engineering. The course aims to develop students' spatial imagination, ability to read and create engineering drawings, and computer-aided design (CAD) skills. It equips students with foundational knowledge of engineering drawing to solve complex engineering problems, skills in graphical representation and analysis of complex engineering problems, and the ability to use computer-aided design tools. It serves as the foundational course for students to study subsequent specialized courses in engineering disciplines.

 

Mechanical Design A

This course is a crucial technical foundation course for mechanical and related engineering programs at the vocational and undergraduate levels in higher education institutions. It primarily focuses on the working principles, structural characteristics, basic design theories, and calculation methods of commonly used mechanisms and general parts in mechanical systems. Through this course, students develop the ability to design, analyze, and integrate various commonly used planar mechanisms and acquire the basic skills to solve practical engineering problems.

 

Engineering Mechanics A

This course is a core course in industrial design, providing a comprehensive introduction to the mechanics theory and calculation methods involved in the static analysis of simple structures and the strength, stiffness, and stability analysis of load-bearing components in engineering. It aims to enable students to understand the analysis of forces on simple components, master the calculation methods for the strength, stiffness, and stability of simple load-bearing members, and possess the ability to perform simple force calculations in the field of mechanical industry with the integration of other knowledge.

 

Morphological construction and Evolution

This course primarily starts with traditional sketching, aiming to enhance students' modeling abilities and creative thinking through an understanding of foundational knowledge and principles of form. Through this course, students develop design awareness, graphic awareness, creative expression awareness, and a mindset for shaping.

 

User Research Methods

This course is based on actual user research cases and emphasizes the thoughts, systems, and methods in the field of user research. It systematically introduces user research methods such as observational techniques, interviewing methods, brainstorming, ethnographic methods, persona methods, lifestyle research methods, POEMS framework, usability evaluation, eye-tracking methods, and insight matrix methods. It also covers topics on user experience design and technological trends, aiming to cultivate students' ability in user research and user experience design.

 

Design Materials

This course provides the material and technical foundation for product design and serves as the basis and prerequisite for product design. Design is realized through the transformation of materials and processes into tangible products, and materials and processes achieve their own value through design. "Design Materials" is one of the important professional foundation courses in industrial design and occupies a significant position in industrial design education. "Design Materials" is an important examinable course offered in the second semester of the second year of industrial design undergraduate program, requiring a total of 80 learning hours. The course includes 48 hours of classroom teaching and 32 hours of self-learning by students outside the classroom.

 

Ergonomics

This course explores the interaction between humans and other factors in a system and applies relevant theories, principles, data, and methods to design for optimizing human and system performance. It is an interdisciplinary field that combines human sciences, engineering, environmental science, sociology, and more. Based on human physiological and psychological characteristics, it aims to create pleasant human-product-environment systems. It applies systematic scientific theories and methods to study the interaction between humans and products, humans and the environment, and humans and society. Human factors are considered as the primary conditions and principles for design. It provides theoretical foundations and methods for developing industrial products and environmental designs that are easy to operate, safe, and comfortable for users, ensuring usability and quality. It offers essential theoretical foundations and design methods for industrial design students to consider human factors in product design, graphic design, environmental design, exhibition design, etc. It integrates human factors throughout the entire process of product development, focusing on the users of the products and ensuring ease of use, learnability, production, and safety, thereby enhancing product usability and quality.

 

Design Methodology

This course is one of the important courses in industrial design. It clarifies the connotation of product design principles, analyzes product design methods, and guides students in understanding and mastering the overall knowledge structure of product design, aiming to elevate students' design abilities to a higher level. Through this course, students are encouraged to approach design problems from a societal perspective, enhance their design awareness and professional qualities, cultivate their professional ethics and sense of social responsibility, grasp the essentials of design with a macroscopic view, deepen their design capabilities, and acquire a comprehensive understanding of industrial design. The course requires students to integrate theoretical knowledge with practical application, further enhance their professional qualities, and lay a foundation for independent analysis and problem-solving in engineering practice.

 

Product Development

Based on the foundation of “Product Design Methodology”, this course further explores related topics in product design, such as market research, customer needs identification, cultural studies, and product image research. The two courses complement each other, enabling students to develop a systematic grasp of product design methods and techniques, and preparing them for careers in product design and related fields. This course is followed by product course design and graduation design projects.

 

Visual Communication Course Design

This course is a practical course aimed at consolidating, deepening, and expanding knowledge related to visual communication design. Through project-based learning, it enhances students’ ability to access and correctly use various literature resources. The course enables students to master the basic procedures and methods of visual identity design and packaging design, integrating a comprehensive application of foundational and professional knowledge to solve visual design problems, and enhancing their understanding and practical skills in graphic design. 

 

Vehicle Engineering

Engineering Drawing A

The course is based on orthographic projection, utilizing the principles of projecting points, lines, and surfaces, along with the drawing methods of section lines and intersection lines. It explores common representation methods for various mechanical components in engineering. This course is a core subject in the education of talent related to mechanical engineering and aims to cultivate students' spatial imagination, drawing skills, geometric drawing skills, and computer-aided design (CAD) capabilities. It serves as a foundational course for subsequent studies in engineering disciplines. Through this course, mechanical engineering students develop the ability to visually represent common mechanical parts, locomotives, process equipment, and gain proficiency in reading relevant engineering drawings.

 

Fundamentals of Electrical and Electronic Engineering

This course is a crucial theoretical and practical foundation for non-electrical majors in higher education institutions. It covers a wide range of content, including multiple fundamental courses in electrical engineering such as circuit theory, electronic technology, motor and control systems, and instrument measurement. The course is highly practical, addressing the extensive and rapidly evolving applications of electrical and electronic technologies. It plays a key role in enhancing students’ ability to apply electrical and electronic technology.

Mechanical Engineering Materials A

This course is a foundational subject for mechanical and related majors. It focuses on the relationship between the properties, composition, structure, and heat treatment of metallic materials. Through this course, students acquire fundamental knowledge of materials in mechanical engineering, develop basic skills in selecting and applying common heat treatment methods, manufacturing processes, and material testing. They also gain the ability to apply basic theoretical analysis to solve engineering problems, considering environmental factors and making rational material choices, laying the necessary groundwork for subsequent specialized courses.

 

Material Mechanics

As a significant technical foundation course in mechanical engineering at universities, it primarily teaches the basic methods of analyzing the structure, motion, and force of various mechanisms, as well as the design and synthesis methods of commonly used mechanisms, laying the groundwork for subsequent courses. The course aims to empower students with the ability to design, analyze, and synthesize various common planar mechanisms, solve practical engineering problems, access technical literature, and utilize general instruments.

 

Mechanical Principle

As a significant technical foundation course in mechanical engineering at universities, it primarily teaches the basic methods of analyzing the structure, motion, and force of various mechanisms, as well as the design and synthesis methods of commonly used mechanisms, laying the groundwork for subsequent courses. The course aims to empower students with the ability to design, analyze, and synthesize various common planar mechanisms, solve practical engineering problems, access technical literature, and utilize general instruments.

 

Machine Design

This course primarily explores the working principles, structural characteristics, basic design theories, and design calculation methods of general mechanical components under common working conditions and within typical parameter ranges. It also covers the design and selection of mechanical system solutions. The teaching of this course enables students in mechanical engineering to master knowledge related to the design and analysis of various mechanical parts, utilize standard specifications to access technical information, and perform experiments on common mechanical components, fostering the ability to design mechanical transmission devices and general machinery.

 

Construction of New Energy Vehicles

This course, a core foundational course for vehicle engineering, plays a crucial role in the talent cultivation plan and curriculum system for the entire vehicle engineering discipline. It comprehensively and systematically discusses the functions, structures, and working principles of automotive engines, chassis in new energy vehicles, as well as the composition and functions of the vehicle body and its accessories. Through this course, students gain systematic knowledge of the construction of new energy vehicles, providing a solid foundation for subsequent courses.

 

Theory of New Energy Vehicles

This course analyzes the main performance aspects of automobiles related to their dynamics, such as power, fuel economy, braking, handling stability, ride comfort, and off-road capability, based on the characteristics of external forces acting on vehicles. It introduces evaluation indicators and methods for each performance aspect, establishes relevant dynamic equations, analyzes the impact of vehicle and component structures and parameters on various performance aspects, and outlines the basic calculation methods for performance prediction.

 

Vehicle Manufacturing Technology

This course is a specialized subject for the vehicle engineering major, addressing the technological discipline of how to efficiently machine automotive components. Guided by the principles of "strengthening process foundations, highlighting automotive priorities, and focusing on skill development," it provides a comprehensive introduction to the basic knowledge and theories of automotive production and manufacturing processes. Main topics include the design of manufacturing fixtures, selection of machining equipment, evaluation of machining quality, calculation of process dimensions, process design, and the compilation of typical processes. The course's mission is to conduct a comprehensive analysis of the manufacturing processes for automotive components based on the rich experience accumulated in automotive production practices. It proposes process improvements to enhance quality, increase labor productivity, and reduce costs. Simultaneously, it nurtures students' patriotism and national pride. Through this course, students gain knowledge in areas such as mechanical machining of automotive components, enabling them to analyze and address relevant production issues and providing a foundational understanding of structural processes for automotive components.

 

New Energy Vehicle Design

This course is one of the compulsory courses for the vehicle engineering major. Through its teachings, students learn to analyze and evaluate the structure and performance of entire vehicles and major assemblies, select rational structural solutions, and methods for relevant parameters. Students also acquire general methods for overall vehicle design and design and calculation methods for major components. The course ensures that students grasp the fundamental theoretical knowledge, basic analytical methods, and general design concepts of vehicle design, providing a solid professional foundation for students in this major.

 

Automotive Testing and Testing Technology

This course is an elective foundational subject for the vehicle engineering major. Through this course, students develop the basic ability to correctly select test equipment, establish the fundamental skills of a testing system, and gain a preliminary understanding of the theoretical and practical aspects of static and dynamic signal testing and analysis. This lays the groundwork for further study, research, and problem-solving related to automotive engineering technology.