Abstract
The reactor power regulating system based on coolant differential temperature across the boiler is inaccurate and sluggish because of the transport delays and time constants associated with temperature measurement. Moreover the control system cannot correct promptly the disturbances transmitted by the secondary system. Above problems can be easily overcome by the reactor control system based on neutron flux measured by the out of core ionisation chambers. The report describes the design and analysis of feedback compensation network based on neutron flux measurement. Closed loop system stability analysis of Kakrapar Atomic Power Plant has been made based on linearised transfer function models of sub-system, to achieve good gain and phase control margins. The control system responses have been tested using reactor functional simulator. The design has been verified by sampled data system analysis using Z transform of the reactor mathematical model. (author). 21 refs., 1 tab.
Bairi, B R;
Dixit, M Y;
Aggarwal, S K;
Ahmed, N;
Das, D
[1]
- Bhabha Atomic Research Centre, Bombay (India). Electronics Div.
Citation Formats
Bairi, B R, Dixit, M Y, Aggarwal, S K, Ahmed, N, and Das, D.
Feedback compensation network design for KAPP reactor regulating system.
India: N. p.,
1992.
Web.
Bairi, B R, Dixit, M Y, Aggarwal, S K, Ahmed, N, & Das, D.
Feedback compensation network design for KAPP reactor regulating system.
India.
Bairi, B R, Dixit, M Y, Aggarwal, S K, Ahmed, N, and Das, D.
1992.
"Feedback compensation network design for KAPP reactor regulating system."
India.
@misc{etde_10132999,
title = {Feedback compensation network design for KAPP reactor regulating system}
author = {Bairi, B R, Dixit, M Y, Aggarwal, S K, Ahmed, N, and Das, D}
abstractNote = {The reactor power regulating system based on coolant differential temperature across the boiler is inaccurate and sluggish because of the transport delays and time constants associated with temperature measurement. Moreover the control system cannot correct promptly the disturbances transmitted by the secondary system. Above problems can be easily overcome by the reactor control system based on neutron flux measured by the out of core ionisation chambers. The report describes the design and analysis of feedback compensation network based on neutron flux measurement. Closed loop system stability analysis of Kakrapar Atomic Power Plant has been made based on linearised transfer function models of sub-system, to achieve good gain and phase control margins. The control system responses have been tested using reactor functional simulator. The design has been verified by sampled data system analysis using Z transform of the reactor mathematical model. (author). 21 refs., 1 tab.}
place = {India}
year = {1992}
month = {Dec}
}
title = {Feedback compensation network design for KAPP reactor regulating system}
author = {Bairi, B R, Dixit, M Y, Aggarwal, S K, Ahmed, N, and Das, D}
abstractNote = {The reactor power regulating system based on coolant differential temperature across the boiler is inaccurate and sluggish because of the transport delays and time constants associated with temperature measurement. Moreover the control system cannot correct promptly the disturbances transmitted by the secondary system. Above problems can be easily overcome by the reactor control system based on neutron flux measured by the out of core ionisation chambers. The report describes the design and analysis of feedback compensation network based on neutron flux measurement. Closed loop system stability analysis of Kakrapar Atomic Power Plant has been made based on linearised transfer function models of sub-system, to achieve good gain and phase control margins. The control system responses have been tested using reactor functional simulator. The design has been verified by sampled data system analysis using Z transform of the reactor mathematical model. (author). 21 refs., 1 tab.}
place = {India}
year = {1992}
month = {Dec}
}