1. P15741: Air Table Mover Photo: Newport.com

2. Team Members Cameron Young – Team Leader Daniel Miller – Lead Mechanical Engineer Nicholas LeBerth – Edge Administrator/ Engineer Curtis Stanard – Lead Industrial Engineer Guides: Professors Hanzlik, Leibfried

3. Agenda Project Description Problem Statement Use Scenarios Customer Requirements Engineering Requirements Risks Project Plan

4. Project Background: Isolation and Air Tables Vibration isolation tables and Optical Breadboards are large surfaces that average in weight from 400 – 2000lbs. Dimensions vary from 3-6 feet wide by 6-20 ft. long During Academic interim periods and scheduled holidays, these large tables need to be transported around the campus.

5. Problem Statement Vibration Isolation Tables are useful when mounting equipment that are sensitive to local vibrations created by the environment, but they are often bulky and difficult to move. The RIT Mechanical Engineering machine shop has been responsible for relocating these isolation tables when necessary. In doing so, the staff has involved methods that incur several risks. These include but are not limited to: injury to the movers/users, damage to the equipment, and damage to the facilities due to lack of appropriate equipment. An improved system is desired in order to move these isolation tables in a faster, safer, and more efficient manner. The end solution will result in a tool and training method that allows two people to effectively move the tables from one place to another without damaging the tables or facilities. The table movement solution will also provide a safe environment during transport. The device(s) needs to easily be stored within a specified footprint area in the machine shop in order to avoid interfering with normal operations when not in use. Problem Summary- The Mechanical Engineering shop is tasked with moving large loads such as isolation tables around campus via unsafe and insufficient means. As a team, we are tasked with developing a commercial-grade system that is capable of transporting a variety of loads.

6. Problem Definition: Stakeholders Operators/Staff – Faculty with experiments requiring Isolation Tables – Facilities Management Customers – Jan Maneti and RIT Machine Shop -RIT and Cooperating Campuses Project Group and Guides Pedestrians

7. Use Scenarios

8. Customer Requirements

9. Engineering Requirements

10. House of Quality Document

11. Constraints System must utilize a form of rotation in order to fit table geometries through a series of standardized door. Must fit in basement storage area System must follow safety codes (check to see if OSHA ASME apply) System must be able to be operated by two people Must fit in freight elevators with table attached.

12. Design Challenges Ensuring Stability of system when in use Rotational Manipulation of tables to fit through doorways Maintaining a safe and ergonomic design for operators Maneuverability over obstructed surfaces

13. Risks Tipping due to size of tables Managing table weight in a safe and efficient manner throughout transport process. Strict adherence to Instructions and Warnings Mobility over uneven surfaces

14. Deliverables Working prototype Corresponding design documents and test data Training manual and Operations Guide

15. Future Assessment and Goals

16. Questions and Feedback

17. Citations http://www.newport.com/Optical-Table- Selection-Guide/140219/1033/content.aspx http://www.newport.com/Optical-Table- Selection-Guide/140219/1033/content.aspx http://www.kineticsystems.com/