Download Members: $0.00 Non‑Members: $75.00 |
Buy Now |
Publication Details
Published Date: | |
---|---|
Authors: | William G. Jansma |
Company: | CMSC |
Print Format: | Technical Paper |
Citation: | William G. Jansma, "An Improvised Two-Dimensional Laser Surface Scanner for Diagnosis of RF Thermionic Electron Gun Problems," The Journal of the CMSC, Vol. 7, No. 1, Spring 2012 |
Abstract
The U.S. Department of Energy’s Advanced Photon Source (APS) at Argonne National Laboratory is a particle accelerator that produces brilliant X-rays for scientific research. To produce X-rays, electrons are accelerated and circulated in a ring 1,104 meters in circumference. The electrons are injected into the accelerator by radio frequency (RF) thermionic electron guns. These devices use heated cathodes to boil off electrons that are then accelerated by RF waves. In early 2010, problems developed in several of the APS electron guns shortly after the replacement of aging cathodes. In an effort to diagnose the problems, the APS Survey and Alignment Section was asked to measure the cathode mating surfaces of the electron guns to identify suspected distortions. Initially the surfaces were measured using an articulating arm CMM with a 3-mm ball probe. Useful data were collected; however, the CMM did not provide the needed resolution. To solve this problem a short-range, noncontact, two-dimensional (2D) laser surface scanner was improvised using equipment on hand. The system uses two charge-coupled device (CCD) laser displacement sensors with 0.5-µm resolution. One sensor is mounted to a high-precision vertical translation rail while the second sensor measures the position of the first. Measurement data is output simultaneously from both sensors, allowing coordinates to be ascertained by combining the data in a spreadsheet. Limited three-dimensional information is obtained by rotating the work piece and scanning across different azimuth angles. Profile plots of the measured coordinates revealed that the cathode mating surfaces were in fact distorted. Results indicate the accuracy of the electron gun profile scans to be on the order of ± 5 µm. This article describes the improvised 2D laser surface scanner and presents the results obtained with the system.