I. General Information
1. Course Title:
Applied Robotic Certification Lab
2. Course Prefix & Number:
RAST 2153
3. Course Credits and Contact Hours:
Credits: 6
Lecture Hours: 0
Lab Hours: 12
4. Course Description:
This course is designed for students desiring to expand their knowledge of specific advanced robotic applications used in industry. These applications may include vision guided robot applications, robotic welding integration, SCADA, robotic offline programming, robot cell simulations, and HMI (human machine interface). Once students select a specific application area, they will plan, document, program and interface the robot(s) and related software and equipment into a completed, functional robotic cell specific for that application.
5. Placement Tests Required:
6. Prerequisite Courses:
RAST 2153 - Applied Robotic Certification Lab
All Credit(s) from the following...
Course Code | Course Title | Credits |
RAST 2151 | Applied Robotics Lab I | 6 cr. |
RAST 2101 | Application Planning & Layout | 2 cr. |
9. Co-requisite Courses:
RAST 2153 - Applied Robotic Certification Lab
There are no corequisites for this course.
III. Course Purpose
Program-Applicable Courses – This course fulfills a requirement for the following program(s):
Robotics/Automated Systems, AAS Degree
Robotics/Automated Systems, Diploma
Applied Engineering Technology, AAS Degree
IV. Learning Outcomes
1. College-Wide Outcomes
College-Wide Outcomes/Competencies |
Students will be able to: |
Analyze and follow a sequence of operations |
Set up advanced programming features. |
Utilize appropriate technology |
Utilize different software and hardware platforms as needed for cell operations. |
Work as a team member to achieve shared goals |
Work as a group to design, build, program and operate the cell. |
2. Course Specific Outcomes - Students will be able to achieve the following measurable goals upon completion of
the course:
- Demonstrate knowledge in integrating program code;
- Demonstrate skills in creating program code;
- Demonstrate analytical skills in robot controller software;
- Analyze a robotic production workflow plan within a manufacturing cell;
- Create and design a robotic production workflow plan;
- Integrate the electronic hardware of the workcell;
- Integrate the software of the workcell;
- Create and design the robotic workcell electrical diagrams;
- Produce a cost benefit analysis of the workcell;
- Compare different hardware and software platforms for functionality;
- Distinguish operational hardware and software faults;
- Create and design a 3D model of the robotic workcell;
- Design and build robotic end of arm tooling;
- Design and build cell fixtures;
- Compose an electrical and mechanical engineering documentation package;
- Plan an operational timeline for implementation of the workcell;
- Prioritize an operational timeline of the workcell;
- Develop hardware and software application-specific fault recovery procedures;
- Develop an operational systems flowchart;
- Integrate required system software platforms;
- Demonstrate knowledge of the cost benefits of the robotic system;
- Develop an operations systems user manual;
- Identify and integrate system safety devices.
V. Topical Outline
Listed below are major areas of content typically covered in this course.
1. Lecture Sessions
2. Laboratory/Studio Sessions
- Demonstrate robot tool frame setup
- Demonstrate robot user frame setup
- Demonstrate robot motion types
- Demonstrate robot safety devices
- Demonstrate robot safety recovery
- Demonstrate robot EOAT operation and functional features
- Demonstrate application documentation procedures
- Software installation
- Software settings and configurations
- Integrate system fault recovery systems
- Integrate system user emergency devices
- Robotic workcell flowchart
- Fault recovery flowchart
- Electrical wiring diagrams
- Mechanical diagrams
- 3D model of working cell components
- Develop an operational flowchart of systems programs
- Determine a cost benefit analysis of the robotic cell
- Determine cell production cycle time
- Compare different equipment software platforms
- Compare different equipment communication proto-calls
- Demonstrate electrical safety procedures
- Demonstrate mechanical safety procedures
- Demonstrate use of a supervisory computer
- Use of different I/O devices and communications between them
- Use of robot to robot file sharing
- Use of robot to robot safety zones
- Cell fixture design and function
- Importing tool frame data from external sources
I. General Information
1. Course Title:
Applied Robotic Certification Lab
2. Course Prefix & Number:
RAST 2153
3. Course Credits and Contact Hours:
Credits: 6
Lecture Hours: 0
Lab Hours: 12
4. Course Description:
This course is designed for students desiring to expand their knowledge of specific advanced robotic applications used in industry. These applications may include vision guided robot applications, robotic welding integration, SCADA, robotic offline programming, robot cell simulations, and HMI (human machine interface). Once students select a specific application area, they will plan, document, program and interface the robot(s) and related software and equipment into a completed, functional robotic cell specific for that application.
5. Placement Tests Required:
6. Prerequisite Courses:
RAST 2153 - Applied Robotic Certification Lab
All Credit(s) from the following...
Course Code | Course Title | Credits |
RAST 2151 | Applied Robotics Lab I | 6 cr. |
RAST 2101 | Application Planning & Layout | 2 cr. |
9. Co-requisite Courses:
RAST 2153 - Applied Robotic Certification Lab
There are no corequisites for this course.
II. Transfer and Articulation
III. Course Purpose
1. Program-Applicable Courses – This course fulfills a requirement for the following program(s):
Robotics/Automated Systems, AAS Degree
Robotics/Automated Systems, Diploma
Applied Engineering Technology, AAS Degree
IV. Learning Outcomes
1. College-Wide Outcomes
College-Wide Outcomes/Competencies |
Students will be able to: |
Analyze and follow a sequence of operations |
Set up advanced programming features. |
Utilize appropriate technology |
Utilize different software and hardware platforms as needed for cell operations. |
Work as a team member to achieve shared goals |
Work as a group to design, build, program and operate the cell. |
2. Course Specific Outcomes - Students will be able to achieve the following measurable goals upon completion of
the course:
- Demonstrate knowledge in integrating program code;
- Demonstrate skills in creating program code;
- Demonstrate analytical skills in robot controller software;
- Analyze a robotic production workflow plan within a manufacturing cell;
- Create and design a robotic production workflow plan;
- Integrate the electronic hardware of the workcell;
- Integrate the software of the workcell;
- Create and design the robotic workcell electrical diagrams;
- Produce a cost benefit analysis of the workcell;
- Compare different hardware and software platforms for functionality;
- Distinguish operational hardware and software faults;
- Create and design a 3D model of the robotic workcell;
- Design and build robotic end of arm tooling;
- Design and build cell fixtures;
- Compose an electrical and mechanical engineering documentation package;
- Plan an operational timeline for implementation of the workcell;
- Prioritize an operational timeline of the workcell;
- Develop hardware and software application-specific fault recovery procedures;
- Develop an operational systems flowchart;
- Integrate required system software platforms;
- Demonstrate knowledge of the cost benefits of the robotic system;
- Develop an operations systems user manual;
- Identify and integrate system safety devices.
V. Topical Outline
Listed below are major areas of content typically covered in this course.
1. Lecture Sessions
2. Laboratory/Studio Sessions
- Demonstrate robot tool frame setup
- Demonstrate robot user frame setup
- Demonstrate robot motion types
- Demonstrate robot safety devices
- Demonstrate robot safety recovery
- Demonstrate robot EOAT operation and functional features
- Demonstrate application documentation procedures
- Software installation
- Software settings and configurations
- Integrate system fault recovery systems
- Integrate system user emergency devices
- Robotic workcell flowchart
- Fault recovery flowchart
- Electrical wiring diagrams
- Mechanical diagrams
- 3D model of working cell components
- Develop an operational flowchart of systems programs
- Determine a cost benefit analysis of the robotic cell
- Determine cell production cycle time
- Compare different equipment software platforms
- Compare different equipment communication proto-calls
- Demonstrate electrical safety procedures
- Demonstrate mechanical safety procedures
- Demonstrate use of a supervisory computer
- Use of different I/O devices and communications between them
- Use of robot to robot file sharing
- Use of robot to robot safety zones
- Cell fixture design and function
- Importing tool frame data from external sources