Alcator C-Mod Weekly Highlights May 11, 1998 A review of the TF magnet was held at MIT on Wednesday, May 6th. Phil Heitzenroeder and Peter Bonanos from PPPL, Phil Edmonds from U. Texas and ITER, Herb Becker from Sigmilon, and Bruce Montgomery from MTechnology were on the review committee. A report will be put together by the review committee chairman, Peter Bonanos. Presentations on the magnet, cooling system, power system, thermal and electromagnetic analysis, and proposed fault and repair scenarios were given. We continue to make procurements, develop procedures, make soldering tests, build new inductive heating coils, design fixturing, and disassemble horizontal magnet arms as we proceed with the magnet repair. The latest inductive heating tests were quite successful in that we both obtained good data from a thermocouple array arranged on the test fixture, and were also able to solder four feltmetal pads onto a finger joint. A 100 kW inductive heating unit is being procured for installation at MIT. Cleanup of the TF core is also proceeding. Finally, a testing station capable of quantifying feltmetal under a variety of temperatures, pressures, and current densities, while sliding is being assembled. Recent invessel work has been devoted to making accurate measurements of the relative position of the outer divertor modules using a gauge that was employed for this same task in 1995. Similar measurements were made at that time before the outer divertor was strengthened with solid pins and stronger mother bolts. These measurements will be compared for any changes in position. A test fit-up of a prototype divertor 'flapper' valve was performed on nine of the ten outer divertor modules. The unit was found to clear all existing in-vessel hardware including the fast-thermocouple array at F-port. Limiter locations were also measured. The FG limiter was found to be slightly tilted left to right (2 mm). Both the FG and GH limiters have been removed so that new diagnostics can be added and old ones reworked where needed. The outer divertor module at F-port was removed from the vacuum vessel. This unit contains the embedded fast-thermocouple and the outer divertor Langmuir probe arrays. Repairs of minor damage to the probe sensors and cabling that occurred over the last two run campaigns will now proceed. William Carmack from INEEL has continued to collect dust from invessel during this up-to-air. A careful sweep of the wall was done shortly after we came up-to-air with a 0.5 um filter. Clusters of small, spherical, molybdenum particles were found along with some glass fibers associated with insulation from cabling for some of our diagnostics. A new sweep under the outer divertor modules has just been completed and the samples have been shipped out to INEEL. We continued our progress on the DNB. We began development of the VAX software that will detect the C-Mod State and facilitate limited control of the beam. This software will be combined with existing timing software to create a package that will integrate the beam firing and conditioning cycle with the C-Mod shot cycle. Work continued on these safety interlocks and the interface of the Master Control Logic (MCL) system to the PLC and to the arc/filament/snubber supply. The prototype grid drive board for the Mod/Reg was completed and is being tested. The construction of the Mod/Reg voltage divider assembly was completed, and its performance is being optimized. Conditioning of the oil in the tank shared by the arc/filament/snubber supplies continued with modest improvement in the breakdown voltage. The arc/filament/snubber cables were terminated at the snubber and an insulating support for their continuation to the source in the test lab was fabricated. Calibration and testing of the control system for the arc notcher was completed. PLC programming for control and monitoring of the suppressor supply and switch, safety interlocks, magnet supply and Mod/Reg were begun. All parts were ordered for the F-port flange which will be the location of the DNB and various other diagnostics. An assembly and installation procedure was developed for the periscope, reciprocating turbulence probe guide tube, and ECE mirrors which are located together in a very compact grouping near the bottom of the flange. These and other aspects of the F-Port flange construction, and the DNB diagnostics will be reviewed on May 20. We continue to make progress on RF projects. FMIT#4 has been disassembled. Initial inspection of the output cavity has found no arc damage; however, a more complete inspection is underway. We intend to use a spare tube to test whether the tube is bad or the arc is in some other part of the transmitter. Preparations for installation of the DC breaks have been completed. The support brackets are in place and the shielding material is on hand. PPPL has offered to supply a female-to-female 9" coaxial elbow to keep the plumbing job moving forward. The backup Inconel shield for the PPPL antenna is out for bids. This bid is being pursued in case the proposed design changes to the TZM shield fail to correct the shock failure problem. Assembly of the antenna in the test stand continues. Paul Bonoli has been successful in modelling advanced tokamak single-null scenarios with ACCOME. He has instituted an error minimization technique which eliminated a convergence problem. Previously, the code would begin to converge upon a solution after several iterations but begin to diverge upon subsequent iterations. Resulting equilibria from the new error minimizations have been cross checked by Jesus Ramos using the CAXE code. We have also begun to work on a patch to connect TORIC with TRANSP until TORIC is fully integrated with TRANSP (PPPL project undertaken by Dan Clark under the supervision of Cynthia K. Phillips). This patch will simply import a TORIC deposition profile into TRANSP. We are implementing this patch because the SPRUCE code in TRANSP has difficulty with off-axis (r/a > 0.5) D(H) minority heating. This patch has the disadvantage that fast particle effects upon wave damping will not be accounted for self-consistently. However, given the high densities at which C-Mod normally operates, this is a minor effect and we will use SPRUCE calculations to estimate a tail temperature to be utilized in the TORIC simulations. Gary Taylor from PPPL visited last week to work on CAMAC and analysis software for the new ECE grating polychromator (GPC2).