8 short-circuit or resistive load, Installation – American Magnetics 05100PS-430-601 High Stability Integrated Power Supply System User Manual

Rev. 3

19

Installation

Operation on a Short-Circuit

For magnet inductance <= 100 Henries (H):

Stability Setting = (100 - H)

For magnet inductance > 100 Henries:

Stability Setting = 0

2.8 Short-Circuit or Resistive Load

If operating with a short-circuit as a load without the presence of a

superconducting magnet, the Model 430 Programmer must be manually

configured for stability. Normally, when the persistent switch heater is

deactivated, the Model 430 Programmer sees essentially a short-circuit

load since the persistent switch shunts all current flow away from any

connected magnet. Therefore, one method of operating a short-circuit is to

indicate that a persistent switch is present, with the persistent switch

heater deactivated.

The preferred method is to indicate that a persistent switch is not present

(see section 3.10.2.6 on page 58) and adjust the stability setting (see

section 3.10.2.1 on page 52) to control the load. A stability setting of 100%

will always allow control of a short-circuit as the load, regardless of the

state of the persistent switch heater.

If the resistance of the load is increased, the stability setting must be

decreased to improve the transient response of the system. If the current

appears to lag, then decrease the stability setting until the system is

responsive. If the current appears to oscillate, increase the stability setting

until the oscillations are damped.

Note

If you have purchased a superconducting magnet with the Model

430 Programmer, AMI will normally provide a recommended

stability setting for optimal operation of the magnet system. If you

operate the Model 430 Programmer with a different load, be sure to

restore the stability setting to the recommended value when the

superconducting magnet is reconnected.

The stability setting is essentially manual control of the gain of an

integrator present in the control logic of the Model 430 Programmer.

Increasing the stability setting decreases the gain of the integrator.

A special case is with the energy absorber designs available from AMI. The

Model 601 Energy Absorber is a nearly infinite-resistance device until 5

Vdc is achieved across its terminals. Once the 5 Vdc “bias” is present, the

Model 601 allows current flow with a nominal 2 mΩ series resistance.

Therefore, the Model 430 Programmer will require an “integration time” to