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Instructive Cultivation Plan for Program of Mechanical Engineering

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Instructive Cultivation Plan for Program of Mechanical Engineering Instructive Cultivation Plan for Program of Mechanical Engineering (FH) (Grade 2018) Program Code: 080201 I. Educational Philosophy According to international development of education resulted by the economic globalization, China's engineering education should adapt to the international demand, to cultivate entrepreneurial and innovative talent, devote oneself to satisfy the international ability of talent. For professional training of specialty in mechanical engineering, we have absorbed foreign advanced engineering education thought and education mode, introduced its successful experience about Fachhochschule ( FH ) for construction of innovative personnel training system, and to train FH-advanced applications talents who masters basic German language skills, and understands the professional and technical knowledge. German University of Applied Sciences (FH mode) cultivates front-line engineers, managers, the economic field staff, and the social and public service personnel. Their educational objectives are consistent with our application-oriented colleges for applying talents cultivation. So in order to cultivate the entrepreneurial and innovative high-skilled personnel in line with international standards, we introduce the German University of Applied Sciences (FH) mode. In this mode, school education is closely integrated with enterprise teaching, so that the student obtain engineering capabilities by the way of initiative, practice and links between the courses, including a deep knowledge of science and engineering technology basics, the ability to use knowledge to solve problems, communication and ability to work in a team, the knowledge innovation ability. The overall goal of professional training is: adapting to the globalization trend of engineering education resulted by the economic globalization, cultivating FH-advanced applications talents who are proficient in German, understands the professional and technical knowledge, have the innovation ability and have the knowledge of the practical experience of the modern enterprise. The program of Mechanical Engineering (FH) is four years. The students are cultivated by university and enterprises. In university, students mainly complete the course learning, acquire engineering and technological knowledge, and humanities and social scientific knowledge. At the same time, students may be obtain the capabilities to analyze and solve practical engineering problems, based on course of experiments, curriculum design, project teaching, and science and technology competitions, practice report - R & D symposium. Students gain the practical professional work experience through learning in the enterprise. The target is to complete the job- based project courses, engineering practice and graduation design, lead to learn the advanced technology and culture, and cultivate the engineering quality, practical and creative abilities and professional ethics. II. Educational Objectives This program is aimed at nurturing FH-style talents in the field of mechanical engineering who masters basic German language skills, has the fundamental knowledge and application skills of mechanical design and manufacturing, and will be engaged in technology development, process design, project management, applications and operation of mechanical and electrical equipment at production site. III. Required Knowledge and Abilities 1. Solid grounding in both natural sciences and humanities & arts; 2. Basic ability of communication, reading and writing using German; 3. A broad understanding of theoretical and technical foundation in mechanical engineering, including mechanics, mechanisms, electrical and electronic techniques, engineering material, machine design, automation, and computer application; 4. Skills of mechanical drafting, calculating, experimenting, testing, literature searching and technical operations; 5. Knowledge of one specialization of mechanical design and manufacturing, and understanding of its trend and current stage of development; 6. Capability of scientific research and development, technology application, management, business sales, and construction operations; 7. Initial experience of learning, practice, design, manufacturing and management in the modern enterprise; 8. Strong active learning ability, critical thinking, innovative spirit, self-conscious spirit of teamwork, and strong expression and communication skills. 4. Duration Generally four years. The shortest duration is not less than three years, and the longest is not more than six years. 5. Credits and Degree Minimum Credits of Curriculum (Comprising course system and intensive practical training): 173. Degrees Conferred: Bachelor of Engineering. 6. Major Disciplines Mechanics, Mechanical design, Mechanical manufacturing, Computer application. 7. Major Courses 7.1 Engineering Design 1 - Technical drawing /CAD (48 hours) “Engineering Design 1 - Technical drawing /CAD” is a basic professional course which is to study the law of drawing and reading of mechanical graphics and to train students to have capabilities of drawing and reading engineering graphics. Through this course, students will be able to understand the basic theory of orthogonal, know how to express the projection of parts, master the expression of the parts and assembly drawings, use general drawing tools and instrument correctly and draw deftly, have computer drawing abilities, grasp general laws and steps for reading engineering drawings and develop a serious and responsible work attitude. The students can master engineering drawings and 3D solid modeling capabilities by computer, including a basic knowledge of the CAE product data management system, the general approach and specific steps to master reading engineering drawings, and comprehensively improve the overall quality of the mechanical disciplines. 7.2 Engineering Mechanics – Statics/ Engineering Mechanics – Dynamics (48hours) "Engineering Mechanics 1 – Statics/ Dynamics" is a very important and basic technological course. Through this course, students can select isolated body from a simple mechanism or structure, accurately draw the force diagram, calculate static force of components and find the constraint forces, understand the methods of solving friction problems in a plane force system, correctly calculate the velocity and acceleration of one point, and angular velocity and angular acceleration of the rigid body, understand the relative movement, grasp the method of point movement and synthesis, correctly calculate the velocity and acceleration of each point on the planar motion rigid body, resolve dynamics problems using dynamics general theorems (such as momentum theorems, theorem of angular momentum, kinetic energy theorem, theorem of mass motion, differential equations of fixed axis rotation, etc.), use the D'Alembert principle to solve the problem of dynamic reaction force, understand the principle of mechanical vibrations. Meantime, this course will train the skills of analyzing, problem solving and communication. The focus of this course is to develop the necessary mechanical analysis and research capabilities of this major. 7.3 Engineering Mechanics - Strength of Materials (48 hours) "Engineering Mechanics 2 - Strength of Materials" is a basic technical course. Through this course, students can generate mechanics sketch from the general pole components, draw internal force diagram of the bars with deformations, to calculate the stress and displacement and calculate strength and stiffness, understand the concept of stress state and strength theory and use them to calculate the strength of bars under combined deformation, understand the method of simple statically indeterminate problem solving, understand the stability concept of the lever, can calculate the critical loads and critical stress of bars with axial force and check the stability, understand the basic concept of the dynamic load, dynamic load coefficients, the fatigue failure and the endurance limit with alternating stress, have the preliminary knowledge of commonly used materials, mechanical properties and their test methods, understand the basic principles of electrical measuring stress analysis. 7.4 Engineering Design 2 - Technical Design and Machine Elements (48hours) "Engineering Design 2 - Technical design and Machine Elements" is a technical foundation course to train students with mechanical design capability. Through this course, the students can determine reasonable design solution according the functional requirements (input and output) and technical requirements. In this course, students can understand basic knowledge of mechanical design, and understand the main types, performance, structural features, applications, materials, standards of mechanical parts, etc. Students can master the basic principles of mechanical design, working principles of mechanical parts, safety regulations to prevent breakage, deformation and fatigue fracture (static / dynamic), stress analysis, stress state, failure modes, calculation criteria of working ability, selection of connecting elements and security elements ,dimensions selection of threaded connection, computing of key connection and interference connection , calculation of rolling bearing (service life and security), etc. Students will be trained with the skills of design calculations, structural design and drawing, experiments, preparation of technical documentation. 7.5 Mechanism Engineering (48 hours) By the learning of the course of "Mechanism Engineering", students can master
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