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4. EL GOCE EFECTIVO DE LOS DERECHOS FUNDAMENTALES COMO LÍMITE A LA PUBLICACIÓN DE ANTECEDENTES PENALES POR PENAS
4.1. CONSULTA EN LÍNEA DE ANTECEDENTES PENALES
4.1.1. Registro para la persona que no tiene antecedentes penales
Industrial Technology courses are listed individually under sub-headings, (e.g., Industrial Technology - Machine Shop/CNC)
Automotive Service Technology - Listed separately Drafting-Mechanical (includes CAD) Electronics - Listed separately Engineering-Mechanical - Listed separately Machine Shop/CNC (includes CAM) Welding
Industrial Technology classes are affiliated with the Society of Manufacturing Engineers and American Welding Society.
185 Directed Study - Industrial Technology (1) CSU - RPT 2 285 Directed Study - Industrial Technology (2) CSU 385 Directed Study - Industrial Technology (3) CSU
Conference 1 hour per unit.
Allows students to pursue Directed Study in Industrial Technology on a contract basis under the direction of a supervising instructor.
911-941
Cooperative Work Experience Education - Industrial Technology (1-4) CSU
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Industrial Technology
(Drafting - Mechanical)
105 Industrial Print Reading I (3) CSU
Lecture 2 hours; Laboratory 2 hours.
Provides training in reading basic engineering blueprints widely used in contemporary manufacturing industries. Both the visualization and interpretation facets of reading are given extensive coverage. Exposure and analysis of common drawing types, views, lines, dimensions, tolerances, callouts, notes, symbology; and revision procedures are included.
110 Mechanical Computer-Assisted Drafting I (3) UC:CSU
Lecture 1 hour; Laboratory 5 hours.
Same as E.M. 110. Credit not given for both courses.
A foundational course in the theory and practice of mechanical computer- assisted drafting. Topics include technical sketching, hardware devices, software utilization, orthographic projection, single and multiple views, and basic dimensioning standards.
115 Mechanical Computer-Assisted Drafting II (3) CSU
Lecture 1 hour; Laboratory 5 hours.
Same as E.M. 115. Credit not given for both courses.
An elementary course in the theory and practice of mechanical computer- assisted drafting. Units include pictorial sketching, computer equipment, software manipulation, isometric projection, oblique projection, and pictorial dimensioning conventions.
205 Technical Descriptive Geometry (3) CSU
Lecture 2 hours; Laboratory 2 hours.
Same as E.M. 205. Credit not given for both courses.
Provides training in the analysis and solution of orthographic projection problems through application of the fundamental principles of descriptive geometry. Emphasis is placed on exposure to and interpretation of points, lines, and planes in primary, secondary, and successive auxiliary views. Theory and practice are included that involve visualization and graphic representation of intersections, angles, parallelism, perpendicularity, and revolutions.
210 Mechanical Computer-Assisted Drafting III (3) CSU
Lecture 1 hour; Laboratory 5 hours.
Same as E.M. 210. Credit not given for both courses.
An introductory course in the principles and practices of mechanical computer-assisted drafting. Areas covered include basic sectional vies, cutting planes, section lining, basic auxiliary views, angle determination, and transfer distances.
215 Mechanical Computer-Assisted Drafting IV (3) CSU
Lecture 1 hour; Laboratory 5 hours.
Same as E.M. 215. Credit not given for both courses.
A basic course in the concepts and skills of mechanical computer-assisted drafting. Units include detail drawings, dimensional tolerancing, feature specification, assembly drawings, parts list generation, and screw thread callouts.
310 Mechanical Computer-Assisted Drafting V (3) CSU
Lecture 1 hour; Laboratory 5 hours.
Same as E.M. 310. Credit not given for both courses.
An intermediate level course in concepts and skills of mechanical computer-assisted drafting. Topics covered include advanced details with multiple sectional views, and advanced details with primary and secondary auxiliary views.
Lecture 1 hour; Laboratory 5 hours.
Same as E.M. 315. Credit not given for both courses.
A mid-level course in the concepts and skills of mechanical computer- assisted drafting. Units include surface texture specification detail assemblies with welding symbology, sheet metal details with flat patterns, and geometric dimensioning and tolerancing.
410 Mechanical Computer-Assisted Drafting VII (3) CSU
Lecture 1 hour; Laboratory 5 hours.
Same as E.M. 410. Credit not given for both courses.
An advanced course in the theory and practice of computer-aided drafting. Topics included will be advanced multiview and pictorial assemblies and complete sets of working drawings that utilize ANSI precision fits in their manufacture.
415 Mechanical Computer-Assisted Drafting VIII (3) CSU
Lecture 1 hour; Laboratory 5 hours.
Same as E.M. 415. Credit not given for both courses.
An advanced course in the theory and practice of computer-aided drafting. Areas of focus will include the construction, editing, and display of three-dimensional wire-frame, surface, and solid models of rectangular and cylindrical parts.
Industrial Technology
(Machine Shop-CNC)
130 Technology of Metal Machining Processes I (3)
Lecture 1; Laboratory 5 hours.
An introduction to the fundamentals of metal-machining processes. Theory is supplemented with demonstrations and/or practice on: lathes, mills, grinders, and drills. The course conveys concepts of metal-machining to: draftspersons, engineers/designers, NC programmers/ operators, QC inspectors; and provides entry-level skills to machinists, machine operators, and toolmakers.
140 Fundamentals of CNC Technology (3)
Lecture 1 hour; Laboratory 5 hours.
Acquaints the beginning student in numerical control with the fundamental concepts underlying this new science. Studies the format and manual preparation of tapes for a variety of basic numerical control Systems. Provides practical experience in the set up and operation of numerical controlled machine tools employing point-to-point, continuous path and circular interpolation machining control.
230 Technology of Metal Machining Processes II (3)
Lecture 1 hour; Laboratory 5 hours.
Recommended Preparation: Industrial Technology 130.
Increases the depth and breadth of understanding of the theoretical concepts and practical skills introduced in Industrial Technology 130. The students will advance their studies in metallurgy theory and practice, engineering materials, metrology, and conventional machining techniques.
244 CNC Programming and Machine Operation - Lathe (3)
Lecture 1 hour; Laboratory 5 hours.
Recommended Preparation: Industrial Technology 140 and 130.
Continues the study of N/C part program preparation begun in Industrial Technology 140 and develops the techniques of planning for efficient operation sequencing. Compares N/C, CNC and DNC; including examination of these techniques in relation to CAD/CAM. Emphasizes writing and running CNC Lathe programs.
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Lecture 1 hour; Laboratory 5 hours.
Recommended Preparation: Industrial Technology 140 and 130.
Acquaints the advanced student with three axis CNC applications involving manufacturing planning, tooling design and/or specification, CNC mill programs employing full 3-axis positioning and implementation of programs using CNC mill equipment in the CAM lab. Students will learn and practice microcomputer assisted part programming of CNC mill.
330 Technology of Metal Machining Processes III (3)
Lecture 1 hour; Laboratory 5 hours.
Recommended Preparation: Industrial Technology 230.
Emphasis is placed on the development of skill and concepts learned in Industrial Technology 130 and Industrial Technology 230 for those persons who will be employed in the metal-machining industry. Close tolerance work will be required. Additional techniques such as jig boring will be introduced.
332 Projects Laboratory in Metal Machining Processes I (3)
Lecture 1 hour; Laboratory 5 hours.
Recommended Preparation: Industrial Technology 230.
The course develops skills in the techniques of design, planning, and execution. Prototype work not possible in regular classes will be covered. Emphasis is placed on developing a project that requires extensive job planning, independent study, and machining.
346 CAM Programming Using Surf CAM (3) CSU
Recommended Preparation: Industrial Technology 140.
Computer-aided manufacturing CNC programming using Surf CAM software. 2D and 3D geometry creation and manipulation, cutter selection & parameters, tool path creation and verification covered. Students will complete CNC programming assignments using Surf CAM.
444 Projects Laboratory-CNC Lathe Programming (3)
Lecture 1 hour; Laboratory 5 hours.
Recommended Preparation: Industrial Technology 244.
Develops skills in the techniques of design, planning, and execution of computer numerical control programs for a CNC lathe. Part programs and CNC programming practices not possible in Industrial Technology 244 will be covered. Emphasis is placed on developing a project to be programmed and machined using a CNC lathe, requiring extensive job planning, independent study and development.
448 Projects Laboratory-CNC Mill Programming (3)
Lecture 1 hour; Laboratory 5 hours.
Recommended Preparation: Industrial Technology 248.
Develops skills in the techniques of design, planing, and execution of computer numerical control programs for a CNC mill. Part programs and CNC programming practices not possible in Industrial Technology 248 will be covered. Emphasis is placed on developing a project to be programmed and machined using a CNC mill, requiring extensive job planning, independent study and development.
601 Robotics Workshop (2)
Lecture 1 hour; Laboratory 2 hours.
Introductory course in Robotics and Manufacturing Technology covering safety, basic circuit theory, resistor color coding, use of DMM , soldering, integrated circuits, microprocessors, Moore’s Law, computer controlled machines and the future of manufacturing. Students will build and program robots and develop computer control programs to operate robots.
602 Advanced Robotics Workshop (2)
Lecture 1 hour; Laboratory 2 hours.
An advanced course in robotics and manufacturing technology covering concepts of feedback control and reactive control of electro-mechanical systems, programming in Basic and C, uses of computers in robot control and metalworking & machining processes. Students will build, program, and operate a walking robot and a competition vehicular robot to be used in inter-school league activities.
911-941
Cooperative Work Experience Education - Industrial Technology (1-4) CSU
See Cooperative Work Experience Education.
Industrial Technology
(Pre-Engineering)
171 Civil Engineering and Architecture (3) CSU
Lecture 1 hour; Laboratory 5 hours.
This course provides an overview of the fields of Civil Engineering and Architecture, while emphasizing the interrelationship and dependence of both fields on each other. Students use state of the art software to solve real world problems and communicate solutions to hands-on projects and activities. This course covers topics such as: the roles of civil engineers and architects, project planning, site planning, building design, project documentation and presentation.
175 Introduction to Engineering Design (3) CSU
Lecture 1 hour; Laboratory 5 hours.
A course that teaches problem-solving skills using a design development process. Models of product solutions are created, analyzed and communicated using solid modeling computer design software.
249 Computer Integrated Manufacturing (3) CSU
Lecture 1 hour; Laboratory 5 hours.
A course that applies principles of robotics and automation. The course builds on computer solid modeling skills developed in Introduction to Engineering Design, and Design and Drawing for Production. Students use CNC equipment to produce actual models of their three-dimensional designs. Fundamental concepts of robotics used in automated
manufacturing, and design analysis are included.
275 Principles of Engineering (3) CSU
Lecture 1 hour; Laboratory 5 hours.
A course that helps students understand the field of engineering and engineering technology. Exploring various technology systems and manufacturing processes help students learn how engineers and technicians use math, science, and technology in an engineering problems solving process to benefit people. The course also includes concerns about social and political consequences of technological change.
278 Digital Electronics (3) CSU
Lecture 1 hour; Laboratory 5 hours.
A course in applied logic that encompasses the application of electronic circuits and devices. Computer simulation software is used to design and test digital circuitry prior to the actual construction of circuits and devices.
Industrial Technology
(Welding)
161 Oxy-Acetylene Welding I (3)
Lecture 1 hour; Laboratory 5 hours.
Gives the beginning student a solid foundation in the principles of oxyacetylene welding and cutting. Emphasizes safety along with related information on equipment, methods and materials.
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Lecture 1 hour; Laboratory 5 hours.
Provides the advanced student with the enhanced concepts and skills required in the oxy-acetylene welding and cutting process. Reviews the basic principles of safety, equipment, methods, and materials then continues with fitting, metallurgy, heat treating, and distortion control factors.
223 General Metallurgy I (4)
Lecture 4 hours.
Presents an in-depth study of the production of ferrous metals, the physical and mechanical properties and characteristics of ferrous and nonferrous alloys. Includes a study of the varying effects of heat and alloy composition relative to structure and properties of various metals.
261 Arc Welding I (3)
Lecture 1 hour; Laboratory 5 hours.
Gives the student a basic foundation in the principles and practices associated with shielded metal arc welding. Emphasizes the rules of safety along with fundamental information on the tools and techniques used in the shielded metal process.
262 Arc Welding II (3)
Lecture 1 hour; Laboratory 5 hours.
Provides the student with the intermediate level concepts and skills required for successful shielded metal arc welding. Reviews essential safety, equipment, and methodology guidelines then continues with mid-level joint preparation and metallurgical effects on weldments.
361 Inert Gas Arc Welding I (3)
Lecture 1 hour; Laboratory 5 hours.
Gives the student a solid foundation in the principles and practices necessary to construct weldments using gas tungsten arc welding. Stresses welding safety and elementary information on the equipment and procedures critical to the gas tungsten process.
362 Inert Gas Arc Welding II (3)
Lecture 1 hour; Laboratory 5 hours.
Provides the student with the intermediate level theory and techniques required for successful gas tungsten arc welding of ferrous and nonferrous metals. Reviews basic safety and equipment information then explores the gas metal and flux cored arc welding processes.
461 Advanced Arc Welding I (3)
Lecture 1 hour; Laboratory 5 hours.
Gives the advanced student the training required to prepare for “Certification” in the Shielded Metal Arc Welding (SMAW) of structural steel. Lecture and practice concentrates on building codes, fabrication techniques, and testing.
462 Advanced Arc Welding II (3)
Lecture 1 hour; Laboratory 5 hours.
Provides the advanced student the skill needed to prepare for
“Certification” in the Gas Metal Arc Welding (GMAW) and Flux Cored Arc Welding (FCAW) of structural steel. Discussion and application concentrates on construction regulations, weldment generation, and inspection.
911-941
Cooperative Work Experience Education - Industrial Technology (1-4)
See Cooperative Work Experience Education.