DSpace Community:http://localhost:8080/xmlui/handle/123456789/3342026-06-23T06:21:29Z2026-06-23T06:21:29ZAzimuth-Altitude Dual Axis Solar TrackerGupta, PreetiKumar, BadalWankhade, PrateekChoudhary, PraveenSingh, Abhijeethttp://localhost:8080/xmlui/handle/123456789/34682022-10-03T06:14:30Z2016-10-30T00:00:00ZTitle: Azimuth-Altitude Dual Axis Solar Tracker
Authors: Gupta, Preeti; Kumar, Badal; Wankhade, Prateek; Choudhary, Praveen; Singh, Abhijeet
Abstract: People in underprivileged countries could benefit from the use of a solar distributed generation
system. To provide an efficient solar distributed generation system, a scaled down dual-axis solar tracker was
designed, built and tested.2016-10-30T00:00:00ZLoad Disturbance Rejection Based PID Controller for Frequency Regulation of a MicrogridKumar, BadalBhongade, Sandeephttp://localhost:8080/xmlui/handle/123456789/34612022-10-03T04:46:13Z2016-07-02T00:00:00ZTitle: Load Disturbance Rejection Based PID Controller for Frequency Regulation of a Microgrid
Authors: Kumar, Badal; Bhongade, Sandeep
Abstract: This paper deals with an autonomous isolated
microgrid comprising both controllable & uncontrollable
sources. Like solar, wind, diesel generator (DG), aqua
electrolyzer (AE), fuel cell (FC), battery energy storage system
(BESS), and fly wheel (FW) are considered. Solar, wind, DG and
FC are power generating source & BESS, FW, AE as energy
storage element. The generated hydrogen by an AE is used as fuel
for a Fe. The power system frequency deviates for the sudden
change in load demand and the real power generation. The
output power of DG, FC, BESS, FW and power absorbed by AE
is regulated by using controller such that frequency of the system
is controlled. Controller used is proportional plus integral plus
derivative (PlD). Load Disturbance Rejection (LDR) is used for
tuning of proposed hybrid system's controller gains. This uses
the chien-hornes-resnick (CRR) setting with 20% overshoot.
The system response of LDR method is compared with classical
method and the result of LDR based controller gives better
response then the classical method.2016-07-02T00:00:00ZSpatial Power Control of Singularly Perturbed Large Nuclear Reactor ?Munje, RavindraPatre, B.Mhttp://localhost:8080/xmlui/handle/123456789/21222019-06-25T08:05:30Z2016-09-11T00:00:00ZTitle: Spatial Power Control of Singularly Perturbed Large Nuclear Reactor ?
Authors: Munje, Ravindra; Patre, B.M
Abstract: Controlling of large nuclear reactors is a challenging task due to simultaneous
presence of both slow and fast varying dynamic modes. This paper presents the design of
linear quadratic regulator for spatial power control of a large Advanced Heavy Water Reactor
(AHWR). The AHWR system is represented by 90 rst order nonlinear di erential equations
with 5 inputs and 18 outputs. After linearization, the original ill-conditioned system of AHWR
is represented into standard singularly perturbed two-time-scale form and decomposed into two
comparatively lower order subsystems, namely, `slow' and `fast' subsystems of orders 73 and 17
respectively. Two individual optimal controllers are developed for both the subsystems and then
a composite controller is obtained for original system. This composite controller is applied to the
vectorized nonlinear model of AHWR. From dynamic simulation in representative transients,
the suggested controller is found to be superior to other methods.2016-09-11T00:00:00ZInvestigation of Spatial Control Strategies for AHWR: A Comparative StudyMunje, R.KPatre, B.M. Londhe, P.STiwari, A.PShimjith, S.Rhttp://localhost:8080/xmlui/handle/123456789/21122019-06-24T11:27:50Z2016-04-01T00:00:00ZTitle: Investigation of Spatial Control Strategies for AHWR: A Comparative Study
Authors: Munje, R.K; Patre, B.M; . Londhe, P.S; Tiwari, A.P; Shimjith, S.R
Abstract: Large nuclear reactors such as the Advanced Heavy
Water Reactor (AHWR), are susceptible to xenon-induced spatial
oscillations in which, though the core average power remains
constant, the power distribution may be nonuniform as well as it
might experience unstable oscillations. Such oscillations influence
the operation and control philosophy and could also drive safety
issues. Therefore, large nuclear reactors are equipped with spatial
controllers which maintain the core power distribution close
to desired distribution during all the facets of operation and following
disturbances. In this paper, the case of AHWR has been
considered, for which a number of different types of spatial controllers
have been designed during the last decade. Some of these
designs are based on output feedback while the others are based
on state feedback. Also, both the conventional and modern control
concepts, such as linear quadratic regulator theory, sliding mode
control, multirate output feedback control and fuzzy control have
been investigated. The designs of these different controllers for the
AHWR have been carried out using a 90th order model, which
is highly stiff. Hence, direct application of design methods suffers
with numerical ill-conditioning. Singular perturbation and timescale
methods have been applied whereby the design problem for
the original higher order system is decoupled into two or three
subproblems, each of which is solved separately. Nonlinear simulations
have been carried out to obtain the transient responses of the
system with different types of controllers and their performances
have been compared.2016-04-01T00:00:00Z