Presentation is loading. Please wait.

Presentation is loading. Please wait.

Design Concepts and Process Analysis for Transmuter Fuel Manufacturing

Published byAlban Osborne Modified over 9 years ago

Similar presentations

Presentation on theme: "Design Concepts and Process Analysis for Transmuter Fuel Manufacturing"— Presentation transcript:

1 Design Concepts and Process Analysis for Transmuter Fuel Manufacturing
Eighth Information Exchange Meeting on Actinide and Fission Product Partitioning and Transmutation Design Concepts and Process Analysis for Transmuter Fuel Manufacturing Georg F. Mauer, Professor Jamil Renno, Graduate Student Department of Mechanical Engineering University of Nevada, Las Vegas UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

2 Design Concepts and Process Analysis for Transmuter Fuel Manufacturing
Table of Contents Introduction Manipulator Dynamics Analysis Of Fuel Fabrication Simulations of Robotic Material Handling Processes Conclusion UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

3 A manufacturing plant for transmuter fuel would have to process considerable quantities in a hot cell. Transmuter Fuel Manufacturing: Approx. 100 tons of Americium fuel annually. UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

4 Transmutation Impact: Lower radiotoxicity
Shorter time frame of concern Smaller volume of waste Optimized waste forms Source: Herczeg 2003 UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

5 Dispersion Fuels (several subtypes exist)
Transmuter Fuel Types With regard to fuel manufacturing, we may distinguish among three categories: Dispersion Fuels (several subtypes exist) Ceramic Fuels (several subtypes exist) Metallic Fuels UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

6 Modeling Fuel Manufacturing Process
3D Drawings of Hot Cell Components Define Dynamic Properties, Kinematic Constraints Command generation, and Equipment Control through Feedback. UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

7 Fuel Fabrication Equipment
Wälischmiller Robot: Modular design All drives and Sensors in Base 30 to 240 kg Load capacity UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

8 Robot Analysis UNIVERSITY OF NEVADA LAS VEGAS
DEPARTMENT OF MECHANICAL ENGINEERING

9 ROBOT PATH PLANNING AND KINEMATICS
The robot model was developed using the Denavit-Hartenberg formulation Arm motion is modeled as a series of successive spatial rotations and translations. For an arm with n joints, the end effector position relative to the base (index 0) is     UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

10 UNIVERSITY OF NEVADA LAS VEGAS
DEPARTMENT OF MECHANICAL ENGINEERING

11 ROBOT PATH PLANNING AND KINEMATICS
    Path generation in Matlab UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

12 Smooth Motion Profile For Trajectory Planning
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

13 Control Law Implementation Simulink and MSC.visualNastran
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

14 (1) Hot Cell Design and Analysis for Powder Processing
Pellet Press Sintering Oven Surface Grinder Inspection Station Cladding Tube UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

15 Possible Floor Plan for Powder Processing
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

16 Hot Cell in Operation Loading Pellets for Insertion into the Cladding Tube
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

17 The simulation permits the detailed analysis of process parameters, such as speed and forces on a fuel pellet. Two examples follow. UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

18 Robot Speed and Forces on Pellet
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

19 Friction Forces on Pellet
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

20 Accident Analysis Collision
Manipulator repeatedly impacts the wall, while moving the pellet to the inspection station.

21 Accident Analysis Collision
Impulses during Collisions with a rigid obstacle.

22 Accident Analysis Pellet Stack Buckling

23 Accident Recovery: Dropping a Pellet

24 Time-Motion Studies Powder Processing
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

25 (1) Time-Motion Studies - Powder Processing
Pellet accelerations not to exceed 20 m/s2 Pick and Place Time Intervals, per pellet. Hot cell with two active Robots. Operation Time in Seconds Robot 1: Image Acquisition (Identify pellet in output tray of the pellet press, select pellet for grasping, compute pellet location and orientation) 5 Pellet Press to Sintering Boat 6 Return robot arm to Pellet Press 4 Total time Robot 1 14 Robot 2: Sintering Boat to Grinder Return robot arm to Sintering Boat Grinder to Dimensional Inspection Station 8 Dimensional Inspection Station to V-tray for Insertion into the cladding tube Total time Robot 2 30 UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

26 Time-Motion Studies - Powder Processing
The time required for pellet handling is small in comparison to the sintering time. (between 1 and 18 hours, depending on process) The time required for the handling metal pins and dispersion fuel compacts will be comparable to those for powder processing, or less. UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

27 Metallic Fuel Processing
Time-Motion Studies Metallic Fuel Processing UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

28 Insertion of Metal Pins into the Cladding Tube
    UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

29 UNIVERSITY OF NEVADA LAS VEGAS
DEPARTMENT OF MECHANICAL ENGINEERING

30 (2) Time-Motion Studies - Metallic Fuel Processing
Pin accelerations not to exceed 20 m/s2 Pick and Place Time Intervals, per pin Hot cell with a single active Robot. Robot Operation Time in Seconds Storage Rack to Grinder 6 Return robot arm to Rack 4 Grinder to Dimensional Inspection Station 8 Dimensional Inspection Station to V-tray for Insertion into the cladding tube Return robot arm to Storage Rack Total time for Robot, per pin 30 UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

31 Dispersion Fuel Processing
Time-Motion Studies Dispersion Fuel Processing UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

32 Dispersion Fuel Manufacture
    UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

33 Design Concepts and Process Analysis for Transmuter Fuel Manufacturing
Conclusion The simulation analysis performs detailed evaluation of the manufacturing process, and detects possible accidents and failures in the hot cell. It allows for the comprehensive examination and testing of failure scenarios as well as recovery procedures, and thus for the iterative optimization of all mechanical hot cell components, ensuring maximum reliability and safety. UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

34 End of Presentation UNIVERSITY OF NEVADA LAS VEGAS
DEPARTMENT OF MECHANICAL ENGINEERING

35     UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

36     UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

37     UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

38 Simulation Examples Pick and Place Operation: Move fuel pellet from sintering press to preparation area for fuel pin loading. UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

39 Simulation Example: Friction Forces during Fuel Pin Loading
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

40 Simulation Example: Torque in Joint 3 (Elbow) during Fuel Pin Loading
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

41 3D Modeling: Robot Simulation
We developed a complete mathematical model of robot kinematics, dynamics, and control. 3D CAD models of hot cell equipment and robots were developed and integrated with the robot dynamics model, using Visual Nastran4D software. Each robot is controlled from Matlab through a Simulink interface with Visual Nastran4D. UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

42 UNIVERSITY OF NEVADA LAS VEGAS
DEPARTMENT OF MECHANICAL ENGINEERING

43 The Robot Controller (Matlab Simulink)
Manipulator dynamics are represented as block ‘vNPlant’     UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

44 Source: J. Breese, DOE, 1999 UNIVERSITY OF NEVADA LAS VEGAS
DEPARTMENT OF MECHANICAL ENGINEERING

45 Fuel Fabrication Equipment
Hot Cell Equipment (Wälischmiller ) UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

46 Fuel Conditioning Facility at ANL West, Idaho Falls. Hot Cell Schematic.
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

47 UNIVERSITY OF NEVADA LAS VEGAS
DEPARTMENT OF MECHANICAL ENGINEERING

48 Transmuter Fuel Fabrication Issues:
Hot cell required Criticality concerns mandate small batch sizes Large fuel quantities suggest process automation Equipment for hot cell operation must be identified or developed. Material flow and operational sequence Long term reliability must be ensured Design must prove he ability to cope with a wide range of contingencies (e.g. equipment failures, spillage, breakage) UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

49 Three processes for Americium Fuel Fabrication (Haas et al.), 1998
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

50 Americium Fuel Fabrication for 1 ton of Am/year (Haas et al.), 1998
UNIVERSITY OF NEVADA LAS VEGAS DEPARTMENT OF MECHANICAL ENGINEERING

Download ppt "Design Concepts and Process Analysis for Transmuter Fuel Manufacturing"

Similar presentations

TECHNOLOGICAL INSTITUTE Center for Robot Technology.

TECHNOLOGICAL INSTITUTE Center for Robot Technology.
From Kinematics to Arm Control a)Calibrating the Kinematics Model b)Arm Motion Selection c)Motor Torque Calculations for a Planetary Robot Arm CS36510.

From Kinematics to Arm Control a)Calibrating the Kinematics Model b)Arm Motion Selection c)Motor Torque Calculations for a Planetary Robot Arm CS36510.
Animating Speed Position and Orientation Presented by Kailash Sawant Hemanth Krishnamachari.

Animating Speed Position and Orientation Presented by Kailash Sawant Hemanth Krishnamachari.
The robot structure model design 2 Curse 5. Modeling: the robot AcTrMStTk V(t) T(t)  (t) q(t) x(t)

The robot structure model design 2 Curse 5. Modeling: the robot AcTrMStTk V(t) T(t)  (t) q(t) x(t)
Mechatronics 1 Weeks 5,6, & 7. Learning Outcomes By the end of week 5-7 session, students will understand the dynamics of industrial robots.

Mechatronics 1 Weeks 5,6, & 7. Learning Outcomes By the end of week 5-7 session, students will understand the dynamics of industrial robots.
USC Viterbi School of Engineering. Information Technology Goals Perform the fundamental research and develop the software components for automating mega-

USC Viterbi School of Engineering. Information Technology Goals Perform the fundamental research and develop the software components for automating mega-
Computer Integrated Manufacturing CIM

Computer Integrated Manufacturing CIM
Manipulator Dynamics Amirkabir University of Technology Computer Engineering & Information Technology Department.

Manipulator Dynamics Amirkabir University of Technology Computer Engineering & Information Technology Department.
Automotive Research Center Robotics and Mechatronics A Nonlinear Tracking Controller for a Haptic Interface Steer-by-Wire Systems A Nonlinear Tracking.

Automotive Research Center Robotics and Mechatronics A Nonlinear Tracking Controller for a Haptic Interface Steer-by-Wire Systems A Nonlinear Tracking.
All logos in this presentation is courtesy of the Florida Institute of Technology Robotics and Spatial Systems Laboratory and the Florida Tech Office of.

All logos in this presentation is courtesy of the Florida Institute of Technology Robotics and Spatial Systems Laboratory and the Florida Tech Office of.
Robust and Efficient Control of an Induction Machine for an Electric Vehicle Arbin Ebrahim and Dr. Gregory Murphy University of Alabama.

Robust and Efficient Control of an Induction Machine for an Electric Vehicle Arbin Ebrahim and Dr. Gregory Murphy University of Alabama.
Chapter 15 Application of Computer Simulation and Modeling.

Chapter 15 Application of Computer Simulation and Modeling.
Industrial Engineering Program King Saud University

Industrial Engineering Program King Saud University
INDUSTRIAL & SYSTEMS ENGINEERING

INDUSTRIAL & SYSTEMS ENGINEERING
1 7M836 Animation & Rendering Animation Jakob Beetz Joran Jessurun

1 7M836 Animation & Rendering Animation Jakob Beetz Joran Jessurun
Manipulator Dynamics Amirkabir University of Technology Computer Engineering & Information Technology Department.

Manipulator Dynamics Amirkabir University of Technology Computer Engineering & Information Technology Department.
Robotics for Manufacturing A Michigan Robotics Focus Area: Contributing Faculty: Kira Barton Chinedum Okwudire Kazuhiro Saitou Dawn M. Tilbury A. Galip.

Robotics for Manufacturing A Michigan Robotics Focus Area: Contributing Faculty: Kira Barton Chinedum Okwudire Kazuhiro Saitou Dawn M. Tilbury A. Galip.
Introduction to Automation Chapter 4 Introduction to Automation Dr. Osama Al-Habahbah The University of Jordan Mechatronics Engineering Department.

Introduction to Automation Chapter 4 Introduction to Automation Dr. Osama Al-Habahbah The University of Jordan Mechatronics Engineering Department.
Manufacturing Engineering Department Lecture 1 - Introduction

Manufacturing Engineering Department Lecture 1 - Introduction
Hardware-In-The-Loop Testbed Team 186: Douglas Pence, Ken Gobin, Aaron Eaddy, Advisor Sung Yeul Park Department of Electrical and Computer Engineering,

Hardware-In-The-Loop Testbed Team 186: Douglas Pence, Ken Gobin, Aaron Eaddy, Advisor Sung Yeul Park Department of Electrical and Computer Engineering,

Similar presentations

Ads by Google