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Self-oscillation in a retroacting thermal conductor

Published online by Cambridge University Press:  24 October 2008

L. B. Turner
Affiliation:
King's College

Extract

In automatic temperature-controlling apparatus a temperature-sensitive element, commonly called a thermostat, serves to increase or decrease a supply of heat to the body or oven whose temperature is to be prevented from changing. The thermostat and heating elements are commonly both electrical, the thermostat comprising a “master coil” whose resistance changes with temperature, the heating element consisting of a “slave coil” carrying the heating current. The temperature of the master coil is made to control the current in the slave coil, usually by the interposition of some form of relay with the appropriate translating and amplifying apparatus. Since every form of relay exhibits “backlash”—the critical values of the operative signal at make and at break are not exactly equal—such a system necessarily oscillates or “hunts” through a range at least as great as the backlash of the relay; and since further there is thermal separation between the master coil and the slave coil, the hunting has a range exceeding the backlash of the relay. It is a common experience with such thermostatic apparatus that, owing to this action, continued improvement towards constancy of temperature is not attainable by increasing the delicacy with which the temperature of the master coil controls the current in the slave coil.

Type
Research Article
Copyright
Copyright © Cambridge Philosophical Society 1936

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References

* Unless, as is theoretically possible, these coils are identical. In actual apparatus, the thermal separation is often very large.

Particulars of this will be published when the work is completed.

* Constantan wire, s.w.g. 44 d.s.c., 1127 ohms.

Nickel wire, s.w.g. 40 d.s.c., about 118 ohms.

Nickel wire, s.w.g. 44 d.s.c., 14 turns.

* But it was observed that when the cover was partly removed, more than doubling the loss, the period was not sensibly altered.

The amplifier belonged to the real-oven equipment. Better precision could have been attained in the present tests if the apparatus had been arranged independently of the work on the real oven.

* 20·3 ohms, Constantan s.w.g. 28 d.c.c., varnished.

* It is interesting to notice that this is about of the loss which would occur in still air without any cover.