Intelligent Home Energy Management Systems for Distributed Renewable Generators, Dispatchable Residential Loads and Distribted Energy Storage Devices

Ajao, Adetokunbo

Author	Ajao, Adetokunbo
Title	Intelligent Home Energy Management Systems for Distributed Renewable Generators, Dispatchable Residential Loads and Distribted Energy Storage Devices
URL	http://hdl.handle.net/2027.42/138102
Publication Date	2017
Date Accessioned	2017-09-05 16:28:56
Degree	MSin Engineering
Discipline/Department	College of Engineering and Computer Science
Degree Level	masters
University/Publisher	University of Michigan
Abstract	The high demand for electricity and the consequent increase in electricity price as lead to recentstudy in reducingthe total operating cost of a residential building. This research work focuson energy management in a residential green house.Two innovative approach is proposed to solve excessiveoperating cost of a residential green house, the system inputs which consist of temperature, activity level, and energyconsumption is based on five household occupant in Atlanta, Georgia, also a Chevy volt of 16kWh is used in the case studies.Moreover, for a single residential house, the overall goal is to reduce the total operating costs and the carbon emissions for a future residential house, while satisfying the end-users’ comfort levels. This paper models a wide variety of home appliances and formulates the economic operation problem using mixed integer linear programming. Case studies are performed to validate and demonstrate the effectiveness of the proposed solution algorithm. Simulation results also show the positive impact of dispatchable loads, distributed renewable generators, and distributed energy storage devices on a future residential house.For networked residential houses, we present an optimization of total operating cost of an interconnected nanogrid (ING) considering the effect of V2H andV2G, which helps tominimizethe total operating cost. The major objective is to reduce carbon emission, total operating cost and the peak load demand while satisfying the customer preferences of each nanogrid. A mixed integer linear program (MILP) is formulated to solve the economic operation of the ING. Furthermore, case studies are performed to demonstrate the positive impact INGs have on minimizing total operating cost.
Subjects/Keywords	Vehicle to Home (V2H); Renewable energy; Vehicle to Grid (V2G); Demand Response; Distributed Energy Storage Device (DESD); Electrical Engineering
Contributors	Su, Wencong (advisor); Niewstadt, Lin Van (committee member); Bai, Kevin (committee member)
Language	en
Rights	Unrestricted
Country of Publication	us
Record ID	handle:2027.42/138102
Repository	umich
Date Retrieved	2020-09-01
Date Indexed	2020-09-09
Grantor	University of Michigan-Dearborn
Issued Date	2017-08-25 00:00:00
Note	[thesisdegreename] Master of Science in Engineering; [thesisdegreediscipline] Electrical Engineering, College of Engineering and Computer Science; [thesisdegreediscipline] College of Engineering and Computer Science; [thesisdegreegrantor] University of Michigan-Dearborn; [bitstreamurl] https://deepblue.lib.umich.edu/bitstream/2027.42/138102/1/Intelligent Home Energy Management Systems for Distributed Renewable Generators, Dispatchable Residential Loads and Distribted Energy Storage Devices.pdf; [filedescription] Description of Intelligent Home Energy Management Systems for Distributed Renewable Generators, Dispatchable Residential Loads and Distribted Energy Storage Devices.pdf : Thesis;

Sample Search Hits | Sample Images | Cited Works

…cost of an interconnected nanogrid (ING) considering the effect of V2H and V2G, which helps to minimize the total operating cost. The major objective is to reduce carbon emission, total operating cost and the peak load demand while satisfying…

…minimizing total operating cost. Key-words: distributed energy storage devices (DESD), renewable energy, demand response, vehicle-to- home (V2H), vehicle-to-grid (V2G). ix CHAPTER 1: INTRODUCTION Commercial and residential…

[1] M. Pipattanasomporn, M. Kuzlu, and S. Rahman, “An algorithm for intelligent home energy management and demand response analysis,” IEEE Trans. Smart Grid, vol.4, pp.2166-2173, Dec. 2012.
[2] W. Su, J. Wang, and D. Ton, “Smart Grid Impact on Operation and Planning of Electric Energy Systems”, Handbook of Clean Energy Systems, Edited by A. Conejo and J. Yan, Wiley, July 2015.
[3] W. Su, and J. Wang, “Energy Management Systems in Microgrid Operations”, The Electricity Journal, vol.25, no.8, pp.45-60, October 2012.
[4] A. Esser, A. Kamper,M. Franke, D. Most, and O. Rentz, “Scheduling of electrical household appliances with price signals,” Oper. Res. Proc., pp. 253–258, 2006.
[5] A. Anvari-Moghaddam, H. Monsef, A. Rahimi-Kian, Optimal Smart home energy management considering energy saving and a comfortable lifestyle, IEEE Transactions on Smart Grid, vol. 6, no. 1, pp. 324-332, 2015.
[6] C. Zhao. S. Dong. F. Li. and Y. Song. "Optimal home energy management system with mixed types of loads," CSEE 1. Power Energy System, vol. I. no. 4. pp. 29-37. dec 2015.
[7] S. Althaher, P. Mancarella, and J. Mutale, "Automated Demand Response from Home Energy Management System under Dynamic Pricing and Power and Comfort Constraints," IEEE Trans.Smart Grid, vol. 6, no. 4, pp. 1874-1883, Jul. 2015.
[8] M.C. Bozchalui, S.A. Hashmi, H. Hassen, C.A. Canizares, and K. Bhattacharya, “Optimal operation of residential energy hubs in smart grids,” IEEE Trans. Smart Grid, vol. 3, no. 4, pp. 1755–1766, Dec. 2012.
[9] O. Erdinc, and N.G. Paterakis, T.D.P. Mendes, A.G. Bakirtzis, and J. P. S. Catalao, “Smart household operation considering bi-directional EV and ESS utilization by real-time pricingbased DR,” IEEE Trans. Smart Grid, vol.6, no.3, pp.1281–1291, May 2015.
[10] I. Sharma, K. Bhattacharya, and C. Cañizares, “Smart distribution system operations with price-responsive and controllable loads,” IEEE Trans. on Smart Grid, vol.6, no.1, January 2015.
[11] M.C. Bozchalui, S.A. Hashmi, H. Hassen, C.A. Canizares, and K. Bhattacharya, “Optimal operation of residential energy hubs in smart grids,” IEEE Trans. Smart Grid, vol. 3, no. 4, pp. 1755–1766, Dec. 2012.
[12] National Weather Service [Online]. Available: http://www.nws.noaa.gov/climate/
[13] Home Energy Software [Online]. Available:http://www.homerenergy.com/HOMER
[14] PJM Day-Ahead LMP Data [online]. Available:http://www.pjm.com/marketsandoperations/energy/dayahead/ lmpda.aspx
[15] Renewable Resource Data Center (NREL), [Online]. Available:http://www.nrel.gov/rredc/
[16] Daft Logic, [Online]. Available:https://www.daftlogic.com/information-appliance-powerconsumption.
[17] MyChevyVolt [Online]. Available: www.mychevroletvolt.com/
[18] R.P.S. Chandrasena, F. Shahnia, S. Rajakaruna and A. Ghosh, “Dynamic operation and control of a hybrid nanogrid system for future community houses,” IET Generation, Transmission & Distribution, vol.9, Issue 11,pp. 1168-1178, 2015.
[19] J. Bryan, R. Duke, and S. Round, “Decentralized generator scheduling in a nanogrid using DC bus signaling”, in Proc. IEEE Power Eng. Soc. Summer Meet., Vol. 1, pp. 977–982, June 2004.
[20] Aniel S. Morais and Luiz A.C. Lopes “Interlink Converters in DC nanogrids and it effect in power sharing using distributed control,” 2016 IEEE 7th International Symposium on Power Electronics for Distributed Generation Systems (PEDG), pp 1-7.
[21] A. Werth, N. Kitamura, and K. Tanaka, "Conceptual Study for Open Energy Systems: Distributed Energy Network Using Interconnected DC Nanogrids, " IEEE Trans. on Smart Grid, vol. 6, no. 4, pp. 1621-1630, July2015.
[22] A. Ajao, J. Luo, Z. Liang, Q.H. Alsafasfeh, and W. Su, "Intelligent Home Energy Management System for Distributed Renewable Generators, Dispatchable Residential Loads and Distributed Energy Storage Devices", The 8-th International Renewable Energy Congress (IREC), 2017.
[23] S. Ganesan, D. Pattabiraman, R. Govindarajan, M. Rajan, and C. Nagamani, “Control scheme for a bidirectional converter in a selfsustaining low voltage DC nanogrid,” IEEE Trans. Ind. Electron., vol. 0046, no. c, pp. 1–1, 2015.
[24] O. Lucia, I. Cvetkovic, H. Sarnago, D. Boroyevich, P. Mattavelli, F. C. Lee, "Design of Home Appliances for a DC-Based Nanogrid System: An Induction Range Study Case," IEEE Journal of Emerging and Selected Topics in Power Electronics, vol. 1, no. 4, pp. 315–326, December 2013.

Open Access Theses and Dissertations