ADVM 0002. Technical Drafting II
Units: 3
Formerly known as DES 2
Prerequisite: Completion of ADVM 1 with grade of "C" or better or equivalent as determined by instructor
Hours: 90 (36 lecture; 54 laboratory which may be scheduled TBA)
Intermediate concepts of engineering design including sections, auxiliaries, threads, fasteners, and dimensional tolerancing. Basic concepts of Geometric Dimensioning and Tolerancing. Design for manufacturability and assembly explored to include material selection and properties of materials. This course teaches intermediate/advanced 3D AutoCAD skills. Designed for students who have attained a fundamental knowledge of the processes and practices of engineering design/drafting. (CSU)
ADVM 0002 - Technical Drafting II
http://catalog.sierracollege.edu/course-outlines/advm-0002/
Catalog Description DESCRIPTION IS HERE: Formerly known as DES 2 Prerequisite: Completion of ADVM 1 with grade of "C" or better or equivalent as determined by instructor Hours: 90 (36 lecture; 54 laboratory which may be scheduled TBA) Description: Intermediate concepts of engineering design including sections, auxiliaries, threads, fasteners, and dimensional tolerancing. Basic concepts of Geometric Dimensioning and Tolerancing. Design for manufacturability and assembly explored to include material selection and properties of materials. This course teaches intermediate/advanced 3D AutoCAD skills. Designed for students who have attained a fundamental knowledge of the processes and practices of engineering design/drafting. (CSU) Units 3 Lecture-Discussion 36 Laboratory 54 By Arrangement Contact Hours 90 Outside of Class Hours Course Student Learning Outcomes Apply appropriate, current and relevant industry standards in preparing technical documentation for the appropriate discipline of their study. Construct partial auxiliary views, half auxiliary views and auxiliary sections and apply them to part drawings. Design complete working drawings in discipline of study for use in manufacturing/building application. Demonstrate computer aided drafting practices that conform to business and industry CAD standards. Demonstrate the appropriate Section view conventions according to the ASME standard for views development. Course Content Outline I. Computer Integrated Manufacturing (CIM) a. Product & Process Definition Review b. Manufacturing Engineering i. Design for Manufacturability (DFM) ii. Design for Assembly (DFA) iii. Design for Service (DFS) iv. Design for Manufacture and Assembly (DFMA) c. Properties of Materials d. Cost and availability of materials e. Appearance, service life, and recycling II. CAD - Drawing Setup a. Pre Planning b. Prototypes i. Conventions and Standards ASME ii. Title and record strips iii. Drawing number iv. Parts list v. Zoning vi. Checking vii. Drafting practices manuals c. CAD specific entities i. Layers ii. Units iii. Blocks/Wblocks iv. Viewports v. WCS/UCS vi. View points III. Sections a. Cutting plane b. Lines in sectioning i. Visible ii. Hidden iii. Center c. Section lining d. Visualizing a section e. Types of sections i. Full ii. Half iii. Revolved iv. Removed v. Broken-out vi. Offset vii. Aligned sections f. Partial views g. Intersections in sectioning h. Conventional breaks IV. Auxiliary Views a. The auxiliary plane b. Reference planes c. Classification of auxiliary views i. Depth auxiliary ii. Height auxiliary iii. Width auxiliary d. Dihedral angle e. Partial auxiliary views f. Half auxiliary views g. Auxiliary sections h. Secondary auxiliaries i. True length lines j. Ellipses V. Threads and Fasteners a. ANSI/Metric Standards i. ANSI/ASME B1.1 ii. ANSI/ASME B1.7M iii. ANSI/ASME B1.13 iv. ANSI/ASME Y14.6 v. ANSI/ASME Y14.6a b. Screw thread terms i. Screw thread ii. External thread iii. Internal thread iv. Major diameter v. Minor diameter vi. Pitch vii. Pitch diameter viii. Lead ix. Angle of thread x. Crest xi. Root xii. Side xiii. Axis of screw xiv. Depth of thread xv. Form of thread xvi. Series of thread c. Screw Thread Forms i. American National 1. Course 2. Fine 3. 8-pitch 4. 12-pitch 5. 16-pitch ii. Unified 1. Extra fine thread iii. Metric iv. Square v. Acme vi. Standard worm vii. Whitworth iix. Knuckle ix. Buttress d. Thread Pitch e. Right/Left handed threads f. Single and multiple threads g. Thread and fastener drawing symbols i. Schematic ii. Simplified iii. Detailed h. Threads in section i. American National thread fits i. Class 1 ii. Class 2 iii. Class 3 j. Metric and Unified thread fits k. Thread notes l. Bolts, studs & screws i. Specifications for bolts and nuts ii. Lock nuts and locking devices iii. Standard cap screws iv. Standard machine screws v. Standard set screws vi. Wood screws m. Keys n. Machine pins o. Rivets p. Springs VI. Introduction to Dimensional Tolerancing a. Tolerance dimensioning b. Size designation c. Fits between mating parts i. Clearance ii. Interference f. Specification of tolerances i. Limit dimensioning ii. Plus-or-minus dimensioning iii. Single limit dimensioning g. Accumulation of tolerances h. Metric system of tolerances and fits VII. Introduction to Geometric Dimensioning and Tolerancing a. Philosophy behind Geometric Dimensioning b. Geometric characteristic symbols i. Symbols for tolerances of position 1. Basic dimension symbol 2. Datum identifying symbol 3. Datum entities 4. Supplementary symbols a. Maximum material condition b. Least material condition c. Regardless of feature size ii. Combined symbols VIII. Assembly Drawings a. General Assembly i. Views ii. Sections iii. Hidden lines iv. Dimensions v. Identification b. Assembly sectioning c. Working drawing assembly d. Installation assemblies e. Check assemblies f. Patent drawings IX. Project a. Design Teams b. Working Drawing c. Assembly Drawings Course Objectives Course Objectives This course requires 36 hours lecture and 54 hours laboratory. In some class sections, the 54 hours of laboratory may be scheduled "to be arranged" or "TBA." The TBA hours and objectives are expected of all students enrolled in the course. Upon successful completion of the course, the student will: Lecture Objectives: I. Computer Integrated Manufacturing (CIM) 1. Explain the role that Design for Manufacturability plays in product design. 2. Describe the benefits that Design for Assembly plays in product design. 3. Describe the benefits that Design for Service plays in product design. 4. Explain the material selection process. 5. Compare and contrast the properties of materials used in product design. II. CAD-Drawing Setup 1. Explain the importance that preplanning plays in drawing setup. 2. Interpret the ASME Standard and apply its conventions. 3. Describe the setup procedures for Computer Aided Design (CAD) specific entities relative to prototypes. III. Sections 1. Differentiate between the symbols used in section lining. 2. Formulate the solution for section development. 3. Differentiate between the types of sections used in drawing development. 4. Analyze the appropriate use of partial views in part descriptions. IV. Auxiliary Views 1. Differentiate between the possible auxiliary planes used in part descriptions. 2. Differentiate between the three main auxiliaries. 3. Describe dihedral angle. 4. Describe true length lines. 5. Describe how ellipses are projected in auxiliary views. V. Threads and Fasteners 1. Apply the ANSI/Metric Standards for application specific conventions. 2. Describe the characteristics of screw threads. 3. Differentiate between screw thread forms. 4. Define the pitch of threads. 5. Describe the difference between right/left hand threads. 6. Describe the difference between single and multiple threads. 7. Differentiate between the classifications for American National thread fits. 8. Differentiate between the Metric and Unified thread fits. VI. Introduction to Dimensional Tolerancing 1. Evaluate how dimensional tolerance affects feature size. 2. Analyze drawings for accumulation of tolerances and how they affect size description. VII. Introduction to Geometric Dimensioning and Tolerancing 1. Describe the rationale behind the system of geometric dimensioning. 2. Evaluate drawings for accurate application of geometric characteristic symbols. VIII. Assembly Drawings 1. Describe the methods used in creating installation assembly drawings. 2. Describe the methods used in creating check assembly drawings. 3. Describe the methods used to create drawings used for patent applications. IX. Semester Project 1. Evaluate the experience working as part of a design team. Laboratory Objectives: I. CAD-Drawing Setup 1. Interpret the ASME Standard and apply its conventions. 2. Describe the setup procedures for Computer Aided Design (CAD)specific entities relative to prototypes. II. Sections 1. Apply the process for cutting plane placement. 2. Apply the standards and conventions for lines in section drawings. 3. Differentiate between the symbols used in section lining. 4. Formulate the solution for section development. 5. Differentiate between the types of sections used in drawing development. 6. Apply the conventions for conventional breaks to views in drawing development. III. Auxiliary Views 1. Construct reference planes for auxiliary views. 2. Construct partial auxiliary views and apply them to part drawings. 3. Construct half auxiliary views and apply them to part drawings. 4. Construct auxiliary sections and apply them to part drawings. 5. Construct secondary auxiliaries and apply them to part drawings. IV. Threads and Fasteners 1. Describe the characteristics of screw threads. 2. Create drawings that employ thread and fastener symbology. 3. Construct appropriate representations for threads in section views. 4. Construct thread notes on drawings for part description. 5. Construct representations for threads and fasteners in drawings. 6. Construct representations keyways and/or keyseats in drawings. 7. Construct representations of machine pins in drawings. V. Introduction to Dimensional Tolerancing 1. Apply tolerance dimensioning to part features. 2. Construct drawings that contain examples of the methods for tolerance dimensioning. 3. Construct drawings that employ the metric system of tolerances and fits. VI. Introduction to Geometric Dimensioning and Tolerancing 1. Apply geometric symbols to part features on drawings. VII. Assembly Drawings 1. Prepare general assembly drawings by applying the ASME standards and conventions. 2. Create drawings that illustrate appropriate assembly sectioning techniques. 3. Create working assembly drawings according to ASME conventions. VIII. Semester Project 1. Create working drawings as an aspect of the document package for the semester project. 2. Create assembly drawings of the semester project to be incorporated into the document package. Methods of Evaluation Objective Examinations Problem Solving Examinations Projects Skill Demonstrations Reading Assignments 1. Students read textbook chapter on Auxiliary View Development then Construct a drawing, based upon course readings, demonstrating the learning objectives. The drawings are evaluated for compliance with ASME standards. Critical thinking and problem solving are part of these assignments. 2. Search the Internet for articles that reference Design for Manufacture and Assembly and be prepared to discuss with the group. Writing, Problem Solving or Performance 1. Compare and contrast methods employed in Design for Manufacture and Assembly- report either written or orally upon return to the lecture. 2. Problem solve the construction of 3D solid models and the relationship of geometry for feature definition. Other (Term projects, research papers, portfolios, etc.) 1. Develop a portfolio that contains samples of semester assignments to show potential employers the engineering design concepts studied. 2. Participate as a member of a design team for the completion of a semester design project. Methods of Instruction Laboratory Lecture/Discussion Distance Learning Other materials and-or supplies required of students that contribute to the cost of the course.
Advanced Manufacturing
http://catalog.sierracollege.edu/departments/advanced-manufacturing/
Gain hands-on skills to design, build and manufacture in the Computer Numeric Control (CNC) machining courses held in our state-of-the-art machining center. This program is affiliated with Gene Haas Foundation of Haas Automation, the largest CNC machine tool builder in the western world.
