Experimental and theoretical studies are made of a typical snap-action
rocker switch, to establish the wear mechanisms in the pivoting contact.
The rocker switch, used extensively in consumer goods, operates in the
medium duty current range, (1 - 30 Amps). Highspeed photographic studies
have shown that the main cause of wear is arcing, occurring during
separation and bounce at the pivot contacts. To reduce the bounce a
computer-based mathematical model of the system dynamics is developed and
optimised; this results in recommended design changes. These changes are
tested under full current endurance conditions, and show significant
improvements in wear.
The model of the switch dynamics relates the mathematics of motion to the
bounce occuring at the pivot contact, without the influence of current.
To show the effect of current and arcing, an automatic test system is
developed for the controlled testing of electrical contacts. The system
has the ability to evaluate arc energy, bounce times, and contact
resistance. The results presented detail the influence of d.c current on
contact bounce time, and identify the importance of the subsequent bounce
time; which is defined for a single make operation, as the total duration
of the bounces occurring after the first bounce. To compare the erosion
profiles of the switch and test system, the system is operated under full
load current endurance conditions, to evaluate wear. This comparison
shows that the wear in the real switch contacts is greater, as result of
the additional contact movement of slip and rolling.
Date of Award | 1986 |
---|
Original language | English |
---|
Awarding Institution | |
---|
ELECTRICAL CONTACT BOUNCE AND THE CONTROL DYNAMICS OF SNAP-ACTION SWITCHES
McBRIDE, J. W. (Author). 1986
Student thesis: PhD