Mechanical manufacturing technology is the original national fine-designed course development, national fine-designed resource sharing class, taught by eight taching team, this course is a course in applied and skilled is outstanding, to foster comprehensive engineering quality and innovation ability as the main line of thinking design, the content covers the cutting tool, machine tool, fixture and machining process knowledge skills, basic course comprehensive, repository, expand resources rich in content.
开设学校:成都工业学院;学科:工学、
Mechanical manufacturing technology is the original national fine-designed course development, national fine-designed resource sharing class, taught by eight taching team, this course is a course in applied and skilled is outstanding, to foster comprehensive engineering quality and innovation ability as the main line of thinking design, the content covers the cutting tool, machine tool, fixture and machining process knowledge skills, basic course comprehensive, repository, expand resources rich in content.
-2.1 Basic knowledge of machine tools
--2.1 Basic knowledge of machine tools
--2.1 Basic knowledge of machine tools
-2.2 Clamping of workpiece
-2.3 The overview of machine tool fixture
--2.3 The overview of machine tool fixture
--2.3 The overview of machine tool fixture
-2.4 Six⁃point locating principle
--2.4 Six⁃point locating principle
--2.4 Six⁃point locating principle
-2.5 Concept of location error
--2.5 Concept of location error
--2.5 Concept of location error
-2.6 the workpiece is positioned on the cylindrical surface
--2.6 the workpiece is positioned on the cylindrical surface
--2.6 the workpiece is positioned on the cylindrical surface
-2.7 The workpiece is positioned on the composite surface
--2.7 The workpiece is positioned on the composite surface
--2.7 The workpiece is positioned on the composite surface
-2.8 Composition of workpiece clamping device and determination of workpiece clamping force
--2.8 Composition of workpiece clamping device and determination of workpiece clamping force
--2.8 Composition of workpiece clamping device and determination of workpiece clamping force
-2.9 The typical clamping device
--2.9 The typical clamping device
--2.9 The typical clamping device
-2.10 Special fixture design
-Chapter Ⅱ Test
-Chapter Ⅱ Machine tools and fixtures
-Chapter Ⅱ Machine tools and fixtures
-3.1 Basic knowledge of tool machining
--3.1Basic knowledge of tool machining
--3.1Basic knowledge of tool machining
-3.2 The force of machining
--3.2 The process of machining
--3.2 The process of machining
-3.3 The force of machining
-3.4 Machining heat and Machining temperature
--3.4 Machining heat and Machining temperature
--3.4 Machining heat and Machining temperature
-3.5 Tool wear, breakage and service life
--3.5 Tool wear, breakage and service life
--3.5 Tool wear, breakage and service life
-3.6 Reasonable selection of metal machining conditions
--3.6 Reasonable selection of metal machining conditions
--3.6 Reasonable selection of metal machining conditions
-3.7 Grinding principle
-3.8 High speed machining and grinding
--3.8 High speed machining and grinding
--3.8 High speed machining and grinding
-Chapter Ⅲ Test
-Chapter Ⅲ The process of machining and control
-Chapter Ⅲ The process of machining and control
-4.1 Fundamentals of machining quality
--4.1 Fundamentals of machining quality
--4.1 Fundamentals of machining quality
-4.2 Machining accuracy
-4.3 Initial error of machining process system
--4.3 Initial error of machining process system
--4.3 Initial error of machining process system
-4.4 The influence of machine tool geometric errors on machining accuracy and its control
--4.4 The influence of machine tool geometric errors on machining accuracy and its control
--4.4 The influence of machine tool geometric errors on machining accuracy and its control
-4.5 The influence of forced deformation of process system on machining accuracy of process system
--4.5 The influence of forced deformation of process system on machining accuracy of process system
--4.5 The influence of forced deformation of process system on machining accuracy of process system
-4.6 Machining errors caused by thermal deformation of process system
--4.6 Machining errors caused by thermal deformation of process system
--4.6 Machining errors caused by thermal deformation of process system
-4.7 The influence of residual stress of workpiece on machining accuracy and its control
--4.7 The influence of residual stress of workpiece on machining accuracy and its control
--4.7 The influence of residual stress of workpiece on machining accuracy and its control
-Chapter Ⅳ Test
-.Chapter Ⅳ Machining Quality
-5.1 Process analysis of mechanical parts
--5.1 Process analysis of mechanical parts
--5.1 Process analysis of mechanical parts
-5.2 Type and selection of parts blank
--5.2 Type and selection of parts blank
--5.2 Type and selection of parts blank
-5.3 The selection principle of finish datum
--5.3 The selection principle of finish datum
--5.3 The selection principle of finish datum
-5.4 The selection principle of rough datum
--5.4 The selection principle of rough datum
-- 5.4 The selection principle of rough datum selection principle of rough datum
-5.5 The selection sample of location datum
--5.5 The selection sample of location datum
--5.5 The selection sample of location datum
-5.6 Selection of surface machining method
--5.6 Selection of surface machining method
--5.6 Selection of surface machining method
-5.7 Process route formulation
--5.7 Process route formulation
--5.7 Process route formulation
-5.8 Machining allowance and operation dimension
--5.8 Machining allowance and operation dimension
--5.8 Machining allowance and operation dimension
-5.9 The concept of Process dimensional chain
--5.9 The concept of Process dimensional chain
--5.9 The concept of Process dimensional chain
-5.10 The calculation of Process dimensional chain
--5.10 The calculation of Process dimensional chain
--5.10 The calculation of Process dimensional chain
-5.11 Numerical control machining technology
--5.11 Numerical control machining technology
--5.11 Numerical control machining technology
-5.12 Economic analysis of process
--5.12 Economic analysis of process
--5.12 Economic analysis of process
-5.13 The establishment and calculation of assembly dimensional chain
--5.13 The establishment and calculation of assembly dimensional chain
--5.13 The establishment and calculation of assembly dimensional chain
-Chapter V Test
-Chapter Ⅴ Design of machining process specification
-Chapter V Design of machining process specificatio
-Final exam
李华志教授,全国优秀教师、首届四川省教书育人名师、四川省高等学校教学名师、四川省有突出贡献的优秀专家、四川省五一劳动奖章获得者。国家精品课程、国家精品资源共享课负责人,四川省精品在线开放课程负责人,四川省高校系统劳模创新工作室负责人,担任四川省科技厅专家库评审专家、工业和信息产业职业教育教指委委员、《机械与电子》杂志编委会委员、开江县科技顾问团专家、校学术带头人。机械设计制造及其自动化专业负责人、机械类专业基础课“机械制造技术”课程负责人,科研团队负责人。一直在教学科研一线从事教学、教改、科研工作,获得四川省教学成果一等奖1项、三等奖2项,主编的教材中2本教材被评为“十一五”国家级规划教材。指导多名学生获得第六届全国大学生机械创新设计大赛四川赛区竞赛一等奖和三等奖各一项,获得第十三届“挑战杯”四川省大学生课外学术科技作品竞赛二等奖并获得优秀指导教师称号。
董军辉:2000年本科毕业于四川大学机械设计及理论专业,2003年硕士毕业于四川大学机械设计及理论专业,获工学硕士学位。2003年7月至今一直在成都工业学院任教,先后承担过《金属切削与机床》和《数控加工工业与装备》等课程。
张慧云:副教授,出生于1978年5月,陕西渭南人。2002年毕业于西南交通大学机械设计及自动化专业,现为机械工程学院机制教研室教师,主要从事机械设计与制造方面的教学与研究工作
宋鸣:1984年毕业于昆明工学院。先后在长城特殊钢公司、成都海普特电子技术科技开发公司的单位工作,于2002年调入原成都电子机械高等专科学校(现成都工业学院)。现任成都工业学院机械工程学院副院长。四川省精品课程《金属切削机床刀具及实训》课程负责人。
四川大学机械制造及其自动化专业,硕士研究生,副教授。从教以来,曾担任“机械制图”、“机械制造技术”等多门课程的主讲任务,是国家级精品课程“数控加工工艺与装备”的主讲教师,是国家级教学团队—“数控技术教学团队”的主要成员。同时,作为项目负责人、主研或参研了多个校级和省级科研任务
陈勇:毕业于沈阳航空工业大学,毕业后在成都飞机工业公司担任工艺及设计工作,后来成都工业学院主要教授机械制造工艺学及机床夹具设计,机械制造技术等课程。
博士,副教授,长期从事新工科建设与改革、智能装备设计与仿真、新能源技术与设备等方面的研究,在国内外期刊发表论文三十余篇,主持、主研多项国家级、省部级科研或教改项目,以及多个横向课题。
本科毕业后在重庆担任机械工艺工程师,硕士毕业于西南交通大学,2018年后在成都工业学院任教,主要教授机床夹具设计、机械制造技术等课程。
李刚俊,男,博士,教授,现任成都工业学院智能制造学院院长,是四川省教育厅“特种机器人”创新科研团队负责人,四川省高校重点实验室“飞控技术实验室”负责人,四川省机械基础实验教学示范中心负责人。研究方向为机器人、机构学及设计理论,具有多年的企业工作经验,曾在加拿大访问研学近三年,具有丰富的理论知识铺垫和国际视野,先后参与了多项国家自然科学基金的研究工作。 李刚俊是四川省高等学校高级职称评审委员,四川省科技厅项目评审专家,四川省机械工程学会机械设计专业委员会委员,四川省机械工程学会摩擦学及表面工程专业委员会常务理事,四川省仪器与自动化学会常务理事,教育部机械原理西南地区研究会常务理事。近年来主持和主研省部级科研、教研项目二十余项。在国家级中文核心期刊等期刊上发表论文40 余篇,其中SCI、EI 检索10 余篇。主编及主审教材4 部,国家专利十多项。指导学生获得多项国家级、省级竞赛奖。