Massive Gas Injection Valve Development for NSTX-U

Raman, R.; Plunkett, G.J.; Way, W.-S.
Issue date: May 2016
Cite as:
Raman, R., Plunkett, G.J., & Way, W.-S. (2016). Massive Gas Injection Valve Development for NSTX-U [Data set]. Princeton Plasma Physics Laboratory, Princeton University.
@electronic{raman_r_2016,
  author      = {Raman, R. and
                Plunkett, G.J. and
                Way, W.-S.},
  title       = {{Massive Gas Injection Valve Development
                for NSTX-U}},
  publisher   = {{Princeton Plasma Physics Laboratory, Pri
                nceton University}},
  year        = 2016
}
Abstract:

NSTX-U research will offer new insight by studying gas assimilation efficiencies for MGI injection from different poloidal locations using identical gas injection systems. In support of this activity, an electromagnetic MGI valve has been built and tested. The valve operates by repelling two conductive disks due to eddy currents induced on them by a rapidly changing magnetic field created by a pancake disk solenoid positioned beneath the circular disk attached to a piston. The current is driven in opposite directions in the two solenoids, which creates a cancelling torque when the valve is operated in an ambient magnetic field, as would be required in a tokamak installation. The valve does not use ferromagnetic materials. Results from the operation of the valve, including tests conducted in 1 T external magnetic fields, are described. The pressure rise in the test chamber is measured directly using a fast time response baratron gauge. At a plenum pressure of just 1.38 MPa (~200 psig), the valve injects 27 Pa.m^3 (~200 Torr.L) of nitrogen with a pressure rise time of 3 ms.

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