| IE:100 and 101 Basic Drafting I-A and I-B 2.5 cr. each S |
| An introductory course covering the fundamentals and foundations of drafting/mechanical drawing. This course will develop student skills in the areas of lettering and sketching techniques, as well as the use of drafting instruments. Major units of instruction will include applied geometry and construction, the drawing and dimensioning of orthographics, pictorial representations, sections and auxiliary views. The student will progress from single view drawings to multi-view detail/working drawings. Labs will closely parallel lecture material. |
| (16 Lec. Hrs./48 Lab Hrs. each course) |
| Prerequisites: IE:100 - None. IE:101 - IE:100. |
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| IE:112 and 113 Machine Drafting I-A and I-B 2.5 cr. each S |
| Advanced drafting course progression from skills developed in DF:108-Basic Drafting or IE:100 and IE:101-Basic Drafting I/A and I/B. Major areas of concentration will include tolerancing, geometric tolerancing, manufacturing processes, fasteners, gearing and cams, welding representations, piping drawing, electronic diagrams and detail working drawings. Lab and lecture hours will be meshed to aid in student understanding. |
| (16 Lec. Hrs./48 Lab Hrs. each course) |
| Prerequisites: IE:112 - IE:101. |
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| IE:120 Descriptive Geometry 2 cr. |
| This course introduces students to basic principles of Descriptive Geometry. These principles are valuable for determining true shapes of planes, angles between two lines, two planes, or a line and a plane, and for locating the intersection between two planes, a cone and a plane, or two cylinders. Problems are solved graphically by projecting points onto selected adjacent projection planes in an imaginary projection system. Major areas of concentration will be orthographic projection, primary auxiliary views, lines, planes, successive auxiliary views, piercing points, intersection of planes, angle between planes, parallelism, perpendicularity, angle between lines and oblique planes, and plane tangencies. |
| (16 Lec. Hrs./32 Lab Hrs. each course) |
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| IE:148 Project Design I 1.5 cr. |
| This course will provide students an introduction to the design process. Students are introduced to some of the design tools used by engineering teams and will cover such topics as 'Whole systems thinking,' 'Teams as a tool in the engineering design process,' 'Creativity and innovation in design,' 'Problem solving processes for design' and 'Communicating a design.' Students will work in teams of two to three and will be required to complete a project during the course of the class. Students will be given a choice of projects from which to choose. |
| (24 Lec. Hrs.) |
| Prerequisites: AU:128 and AU:129. |
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| IE:149 Project Design II 1.5 cr. |
| This class will build on the skills and techniques learned in Project Design I. Students will work in teams of two or three and will cover topics to include 'From concept to delivery: Managing the project,' 'Quality through the design review process' and 'Delivering the product.' Each team will be required to complete an assigned project during the course of the class. |
| (24 Lec. Hrs.) |
| Prerequisites: IE:148 |
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| IE:203 and 204 Fundamentals of AutoCAD 2000 I-A And I-B 2 cr. each S |
| A beginning course to upgrade the student's conventional drafting skills using a Computer Aided Drafting system instead of traditional manual drafting instruments. This course will include the use of AutoCAD 2000 training software/hardware that is comparable to equipment used in regional industry. |
| (16 Lec. Hrs./32 Lab Hrs. each course) |
| Prerequisites: IE:203 - IE:101 or instructor's approval. IE:204 - IE:203. |
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| IE:206 Fundamentals of AutoCad 4 cr. S |
| This is a tutorial-based course covering the fundamentals of AutoCad. Students begin with basic shapes and work through multiview drawings in a series of extensive hands-on tutorial lessons. The AutoCad Heads-Up Design Interface is also covered allowing students to concentrate on design intent rather than the keyboard. Other areas of coverage include the WYSIWYG (What You See Is What You Get) plotting feature as well as Named Plot Style and Layout Plotting. During the course students will cover object properties and organization through layers, orthographic views, dimensioning and notes, auxiliary views and GRIPS, section views, blocks and assembly drawings. |
| (32 Lec. Hrs./64 Lab Hrs.) |
| Prerequisites: IE:100 and IE:101. |
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| IE:213 and 214 Intermediate AutoCAD 2000 I-A And I-B 2 cr. each S |
| This course is a follow up to IE:203 and IE:204, where students use the various principles to complete more complex mechanical drawings and electrical and piping diagrams. This course will include the use of AutoCAD 2000 training software/hardware that is comparable to equipment used in regional industry. |
| (32 Lec. Hrs./64 Lab Hrs. each course) |
| Prerequisites: IE:213 - IE:203 and IE:204 or instructor's approval. IE:214 - IE:213 or instructor's approval. |
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| IE:215 Solid Works - Basic 4 cr. S |
| This is a tutorial-based course covering the basics of Solid and Parametric modeling using Solid Works. Students will learn the fundamentals of solid modeling with Solid Works through a series of competency-based projects. Students will learn through a progressive approach from chapter to chapter. Beginning with extruded and revolved features, students move through sweeps, lofts, ribs and patterned features. Ending with sub-assemblies, assemblies and finally fundamentals of drawing. As in most solid/parametric modeling packages, parts, drawing and assemblies have an associated relationship with each other. |
| (32 Lec. Hrs./64 Lab Hrs.) |
| Prerequisites: IE:100 and IE:101. |
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| IE:231 Pro Engineer - Basic Modeling 4 cr. S |
| This is a tutorial-based course covering the basics of Solid and Parametric modeling using Pro Engineer. Students will learn the fundamentals of solid modeling with Pro Engineer through a series of 11 tutorial-based lessons that include the use of a Multimedia CD. Along with exercises at the end of each lesson students will also create projects for use during the assembly and detailing lessons. Students begin by becoming familiar with the user interface, model structure and view controls. These concepts are followed by the creation of simply extruded protrusions and the use of the higher end functionality to create revolved protrusions, mirror copies, rounds and protrusions. The redefine, sketcher tools and patterns and copies. Engineering drawings, assembly functionality and sweeps and blends give the students a good sound base for Pro Engineer - Advanced. The final project for the course is a full assembly of a Panavise complete with engineering drawings. |
| (32 Lec. Hrs./64 Lab Hrs.) |
| Prerequisites: IE:100 and IE:101. |
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| IE:233 Basic Detailing 4 cr. S |
| This is a course designed for technicians and designers who must use Pro Engineer’s Drawing functionality. Students will learn how to create orthographic views of part models to be used in detail drawings. Students will completely dimension drawings using title block formats, design tolerancing and GD and T. Students will also create assembly drawings and bill of materials using the table command. Multiple sheet drawings and multi-model drawings will also be created. |
| (32 Lec. Hrs./64 Lab Hrs.) |
| Prerequisites: Instructor's approval. |
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| IE:241 Advanced Modeling 4 cr. S |
| This is a tutorial-based follow-up course to Pro Engineer - Basic. Students take the skills they learned in the basic class and expand on that functionality. Students are assumed to have familiarity with basic Pro Engineer functionality as this information is taken for granted. Through tutorial exercises students learn to use higher end commands such as sweeps, round sets, UDF's, drafts and tweaks, patterns and family tables. Other areas of coverage include layers, Pro Program and advanced drawing and assembly functions. As in the preceding course, students will create parts in the exercises at the end of each lesson as well as parts for a main project. The project at conclusion of the course allows students to use previously acquired problem solving and design skills. |
| (32 Lec. Hrs./64 Lab Hrs.) |
| Prerequisites: IE:100, IE:101 and IE:231. |
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| IE:243 Advanced Detailing 4 cr. S |
| This course is designed for the user who creates and manipulates large or multiple sheet drawings. Students will use Pro Engineer's layer control and feature show capabilities to create advanced detail drawings. Exploded assemblies and tabulated drawings will be covered, as will simplified reps, the use of symbols, ordinate dimensions and created and shown dimensions. |
| (32 Lec. Hrs./64 Lab Hrs.) |
| Prerequisites: Instructor's approval. |
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| IE:251 Assemblies 4 cr. S |
| This course is for the designers who will create assemblies from existing parts. The constraint functionality of Pro Engineer will be used to create multiple part assemblies as well as sub-assemblies. Students will learn the differences between Top Down and Bottom Up assemblies. Students will use the start part and start assembly tools in assembly creation. Troubleshooting and redefining assembly constraints will also be emphasized. Students will also learn to modify the assembly explode states for assembly drawing creation. |
| (32 Lec. Hrs./64 Lab Hrs.) |
| Prerequisites: Instructor's approval. |
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| IE:256 Pro Engineer - Sheet Metal 4 cr. S |
| This is a tutorial/project-based course aimed at teaching students the methods of utilizing the functionality of Pro Engineer - Sheet Metal. The projects have been developed to teach functionality through a series of projects, each with defined objectives and outcomes. Students will complete projects that will include sheet metal parts, detail drawings, assemblies, bend order tables and complete bill of materials. A good foundation of basic Pro Engineer is required and students should have strong drafting skills. Students will create various types of walls, cuts, chamfers, relief cuts and flat pattern geometry. Other areas of emphasis will include transitions, rolls, twists and louvers. During the modeling process students will gain expertise with bend tables and fasteners during assembly. |
| (32 Lec. Hrs./64 Lab Hrs.) |
| Prerequisites: IE:100, IE:101 and IE:231. |
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| IE:257 Pro Engineer - Basic Milling 4 cr. S |
| This course covers the basic fundamentals of NC Milling using Pro Engineer. It is designed for programmers using Pro NC and Programming on 3 - 5 axis NC machines. Students will learn to create simple NC programs by combining the model, coordinate system, machining and tooling parameters to create tool paths. Basic profiling operations involving step depth, multiple passes and lead in and out will be covered. Students will identify and use the machine coordinate system and use NC Check to verify operations. Hole making and surface milling will be addressed as well as face milling and manipulation of tool paths. Finally, students will use Pro Engineer's post processing functionality to create machine code. |
| (32 Lec. Hrs./64 Lab Hrs.) |
| Prerequisites: IE:231, IE:233 and IE:251. |
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| IE:259 Pro Engineer - Basic Turning 2 cr. S |
| This course covers the basic fundamentals of NC Turning using Pro Engineer. It is designed for programmers needing to create two and four axis tool paths for machining on a CNC lathe. Specifically, students will learn to create the five types of turning sequences; area, profile, groove, thread and hole making. Additionally, all of these sequences, except hole making, can be used to create outside, inside or facing sequences. |
| (16 Lec. Hrs./32 Lab Hrs.) |
| Prerequisites: IE:231, IE:233 and IE:251. |
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| IE:290 AutoDesk Inventor 4 cr. S |
| This is a tutorial-based course covering the basics of Solid and Parametric modeling using AutoDesk Inventor. Students begin by creating basic shapes and work into intelligent solid models and assemblies and then multi-view drawings. The text uses a series of tutorial-based lessons to achieve this. Students begin with the fundamentals of parametric modeling and proceeding through solid geometry concepts, the model tree, parametric constraints, the BORN technique, geometric construction tools, parent/child relationships and assemblies. Although AutoDesk Inventor is the software used in this course, the techniques and concepts apply to many solid and parametric modeling packages. |
| (32 Lec. Hrs./64 Lab Hrs.) |
| Prerequisites: Instructor's approval. |
