Your search keyword '"Bhattacharya, Kankar"' showing total 7 results

1. Material Flow Based Power Demand Modeling of an Oil Refinery Process for Optimal Energy Management.

Author

Alarfaj, Omar and Bhattacharya, Kankar

Subjects

*ENERGY management, *PETROLEUM refineries, *GROUNDWATER flow, *COGENERATION of electric power & heat, *ELECTRIC power consumption, *ELECTRICITY pricing

Abstract

Oil refining is an energy-intensive industry, that is often equipped with different types of distributed generation (DG) resources. Optimal energy management of the refinery's load and its DG resources, under dynamic electricity pricing, improves electricity consumption behavior of the facility and hence reduces its energy costs. An energy management system (EMS) model is proposed in this paper for minimizing electricity consumption costs of an oil refinery facility considering on-site cogeneration capability. The energy management is based on power demand modeling of the oil refinery process. A joint electrical–thermal model is used for the cogeneration units to account for the electricity and steam production. The developed EMS model is also used as part of a demand response strategy to illustrate the impact of EMS decisions on distribution system operations. [ABSTRACT FROM AUTHOR]

Published

2019

2. Probabilistic Distribution Load Flow With Different Wind Turbine Models.

Author

Ahmed, Mohamed Hassan, Bhattacharya, Kankar, and Salama, Magdy M. A.

Subjects

*ELECTRIC power distribution, *WIND turbines, *WIND power, *ELECTRIC potential, *ELECTRIC power systems research

Abstract

This paper presents a novel probabilistic distribution load flow (PDLF) algorithm to study the effect of connecting a wind turbine (WT) to a distribution system. This probabilistic approach is used to capture the stochastic behavior of the generation of WTs. Three different models of WTs are developed to be embedded in the PDLF. Consequently, a probabilistic approach to evaluate the impact of wind penetration into distribution systems is developed. Futhermore, the effect of WT penetration on feeder losses, voltage profile and substation powers is presented. [ABSTRACT FROM PUBLISHER]

Published

2013

3. Self-Scheduling Models of a CAES Facility Under Uncertainties.

Author

de Souza, Matheus F. Zambroni, Canizares, Claudio A., and Bhattacharya, Kankar

Subjects

*COMPRESSED air energy storage, *MONTE Carlo method, *UNCERTAINTY, *ROBUST optimization

Abstract

This paper presents two mathematical formulations to represent uncertainties in self-scheduling models of a price-taker Compressed Air Energy Storage (CAES) facility. The proposed model is from the point of view of the plant owner participating in the energy, spinning, and idle reserve markets. The first described formulation is based on Robust Optimization (RO) and the second one is based on Affine Arithmetic (AA) techniques, which are both range arithmetic methodologies, and consider the thermodynamic characteristics of the CAES facility for a more realistic representation. The implementation of both methods are tested, validated and compared with each other and with Monte Carlo Simulations (MCS) using prices from the Ontario market. From the simulation results, it can be observed that both methods have some similarities, presenting lower computational burden compared with MCS, and demonstrate the advantage of applying the proposed models for CAES plant owners to hedge against price uncertainties. [ABSTRACT FROM AUTHOR]

Published

2021

4. Inclusion of Battery SoH Estimation in Smart Distribution Planning With Energy Storage Systems.

Author

Alrumayh, Omar, Wong, Steven, and Bhattacharya, Kankar

Subjects

*ENERGY storage, *DISTRIBUTION planning, *ENERGY management, *HOUSEHOLD appliances, *DISTRIBUTION management

Abstract

Energy storage systems (ESSs) can improve energy management in distribution grids, especially with the increasing penetration of home energy management systems (HEMSs) that schedule household appliances and render them as smart loads. A large number of uncoordinated HEMSs can result in significant changes to the aggregated load profile of the distribution system. This paper proposes a framework and mathematical model for integrating ESS in the distribution grid to minimize the operation cost of the local distribution company (LDC) and alleviate the impact of uncoordinated HEMS operation on the distribution grid. A novel neural network (NN) based state of health (SoH) estimator for a lithium-ion (Li-ion) battery based ESS is proposed, which is incorporated within the LDC's planning problem. The results show that the proposed estimation model is an accurate estimation of the SoH of the ESS. The LDC's planning decisions are also compared, considering SoH of the ESS vis-á-vis linear degradation and no-degradation models. [ABSTRACT FROM AUTHOR]

Published

2021

5. Optimal Operation of Distribution Feeders in Smart Grids.

Author

Paudyal, Sumit, Canizares, Claudio A., and Bhattacharya, Kankar

Subjects

*ELECTRIC networks, *ELECTRIC power distribution, *ELECTRICAL load, *CAPACITORS, *ELECTRIC switchgear, *MATHEMATICAL optimization, *MATHEMATICAL models

Abstract

This paper presents a generic and comprehensive distribution optimal power flow (DOPF) model that can be used by local distribution companies (LDCs) to integrate their distribution system feeders into a Smart Grid. The proposed three-phase DOPF framework incorporates detailed modeling of distribution system components and considers various operating objectives. Phase specific and voltage dependent modeling of customer loads in the three-phase DOPF model allows LDC operators to determine realistic operating strategies that can improve the overall feeder efficiency. The proposed distribution system operation objective is based on the minimization of the energy drawn from the substation while seeking to minimize the number of switching operations of load tap changers and capacitors. A novel method for solving the three-phase DOPF model by transforming the mixed-integer nonlinear programming problem to a nonlinear programming problem is proposed which reduces the computational burden and facilitates its practical implementation and application. Two practical case studies, including a real distribution feeder test case, are presented to demonstrate the features of the proposed methodology. The results illustrate the benefits of the proposed DOPF in terms of reducing energy losses while limiting the number of switching operations. [ABSTRACT FROM AUTHOR]

Published

2011

6. Smart Residential Load Simulator for Energy Management in Smart Grids.

Author

Lopez, Juan Miguel Gonzalez, Pouresmaeil, Edris, Canizares, Claudio A., Bhattacharya, Kankar, Mosaddegh, Abolfazl, and Solanki, Bharatkumar V.

Subjects

*SMART power grids, *AMBIENT temperature ferrite process, *ENERGY management

Abstract

This paper describes the development of a freeware smart residential load simulator to facilitate the study of residential energy management systems in smart grids. The proposed tool is based on MATLAB-Simulink-GUIDE toolboxes and provides a complete set of user-friendly graphical interfaces to properly model and study smart thermostats, air conditioners, furnaces, water heaters, stoves, dishwashers, cloth washers, dryers, lights, pool pumps, and refrigerators, whose models are validated with actual measurements. Wind and solar power generation as well as battery sources are also modeled, and the impact of different variables, such as ambient temperature and household activity levels, which considerably contribute to energy consumption, are considered. The proposed simulator allows modeling of appliances to obtain their power demand profiles, thus helping to determine their contribution to peak demand, and allowing the calculation of their individual and total energy consumption and costs. In addition, the value and impact of generated power by residential sources can be determined for a 24-h horizon. This freeware platform is a useful tool for researchers and educators to validate and demonstrate models for energy management and optimization, and can also be used by residential customers to model and understand energy consumption profiles in households. Some simulation results are presented to demonstrate the performance and application of the proposed simulator. [ABSTRACT FROM AUTHOR]

Published

2019

7. Battery Energy Storage System Models for Microgrid Stability Analysis and Dynamic Simulation.

Author

Farrokhabadi, Mostafa, Konig, Sebastian, Canizares, Claudio A., Bhattacharya, Kankar, and Leibfried, Thomas

Subjects

*MICROGRIDS, *STABILITY (Mechanics), *STORAGE batteries, *VOLTAGE-frequency converters, *ELECTRIC power system stability, *HARMONIC distortion (Physics)

Abstract

With the increasing importance of battery energy storage systems (BESS) in microgrids, accurate modeling plays a key role in understanding their behavior. This paper investigates and compares the performance of BESS models with different depths of detail. Specifically, several models are examined: an average model represented by voltage sources; an ideal dc source behind a voltage source converter; a back-to-back buck/boost and bidirectional three-phase converter, with all models sharing the same control system and parameters; and two additional proposed models where the switches are replaced by dependent sources to help analyze the differences observed in the performance of the models. All these models are developed in PSCAD and their performances are simulated and compared considering various issues such as voltage and frequency stability and total harmonic distortion in a benchmark test microgrid. It is shown through simulation results and eigenvalue studies that the proposed models can exhibit a different performance, especially when the system is heavily loaded, highlighting the need for more accurate modeling under certain microgrid conditions. [ABSTRACT FROM AUTHOR]

Published

2018