A.13.3.1 magnet charging, Appendix – American Magnetics 03300PS-430-601 High Stability Integrated Power Supply System User Manual

Rev. 5

173

Appendix

Model 601 and Energy Absorption

A.13.3

Model 601 Energy Absorber Functional Description

The Model 601 provides a constant reverse voltage source of 5 Vdc. With

this configuration, as the power supply voltage is reduced below 5 Vdc, a

net reverse voltage allows controlled, active discharge of the magnet.

This requires power supplies capable of voltages higher than 5 Vdc for

charging, a requirement that is met by the basic 0 to +10 Vdc rated

08150PS Power Supply unit. The following paragraphs discuss basic

magnet charging, discharging, and application of the Model 601 with

unipolar power supplies.

A.13.3.1 Magnet Charging

Whenever the current flowing in an inductor changes, whether due to an

external influence such as a power supply or from natural decay of the

field, the inductor always presents a terminal voltage in the direction that

would preserve the former current rate of flow (i.e., oppose the change).

The magnitude of this opposing voltage is equal to the current rate of

change (Amperes per second) multiplied by the inductance (Henries). In

mathematical symbols, V = L x (di/dt)

1

.

In charging a magnet, the power supply must provide this voltage plus

additional voltage to overcome loop IR (V = i x R) voltage drops

2

(due

primarily to lead/cable resistance); thus V = L x (di/dt) + V

lead

(refer to

1. Refer also to “Ramping Functions” on page 79
2. Lead and other small circuit resistances are on the order of one or

two hundredths of an Ohm. V

lead

varies with current but is depicted

in the drawings arbitrarily as 0.5 Vdc (superconducting magnet resis-
tance is essentially zero so there is no inductor IR drop).

Figure A-3.

Loop Voltages - Actively Discharging (with Model 601)