Relevant bibliographies by topics / Energy storage – Ontario

Academic literature on the topic 'Energy storage – Ontario'

Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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Journal articles on the topic "Energy storage – Ontario"

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Bassett, Kyle, Rupp Carriveau, and David S. K. Ting. "Energy arbitrage and market opportunities for energy storage facilities in Ontario." Journal of Energy Storage 20 (December 2018): 478–84. http://dx.doi.org/10.1016/j.est.2018.10.015.

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Ozbilen, A., I. Dincer, G. F. Naterer, and M. Aydin. "Role of hydrogen storage in renewable energy management for Ontario." International Journal of Hydrogen Energy 37, no. 9 (May 2012): 7343–54. http://dx.doi.org/10.1016/j.ijhydene.2012.01.073.

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Kadri, Abdeslem, and Farah Mohammadi. "Energy storage optimization for global adjustment charge reduction in Ontario." Journal of Energy Storage 30 (August 2020): 101491. http://dx.doi.org/10.1016/j.est.2020.101491.

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Chen, Jiaxin, Stephen J. Colombo, Michael T. Ter-Mikaelian, and Linda S. Heath. "Future carbon storage in harvested wood products from Ontario’s Crown forests." Canadian Journal of Forest Research 38, no. 7 (July 2008): 1947–58. http://dx.doi.org/10.1139/x08-046.

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This analysis quantifies projected carbon (C) storage in harvested wood products (HWP) from Ontario’s Crown forests. The large-scale forest C budget model, FORCARB-ON, was applied to estimate HWP C stock changes using the production approach defined by the Intergovernmental Panel on Climate Change. Harvested wood volume was converted to C mass and allocated to four HWP end-use categories: in use, landfill, energy, and emission. The redistribution of C over time among HWP end-use categories was calculated using a product age-based C-distribution matrix. Carbon emissions for harvest, transport, and manufacturing, as well as emission reductions from the use of wood in place of other construction materials and fossil fuels were not accounted for. Considering the wood harvested from Ontario Crown forests from 1951 to 2000 and the projected harvest from 2001 to 2100, C storage in HWP in use and in landfills is projected to increase by 3.6 Mt·year–1 during 2001–2100, with an additional 1.2 Mt·year–1 burned for energy. Annual additions of C projected for HWP far outweighs the annual increase of C storage in Ontario’s Crown forests managed for harvest, which is projected to increase by 0.1 Mt·year–1 during the same period. These projections indicate that regulated harvest in Ontario results in a steadily increasing C sink in HWP and forests. Uncertainties in HWP C estimation are also discussed.
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Gaede, James, and Ian H. Rowlands. "How ‘transformative’ is energy storage? Insights from stakeholder perceptions in Ontario." Energy Research & Social Science 44 (October 2018): 268–77. http://dx.doi.org/10.1016/j.erss.2018.05.030.

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Konrad, James, Rupp Carriveau, Matt Davison, Frank Simpson, and David S. K. Ting. "Geological compressed air energy storage as an enabling technology for renewable energy in Ontario, Canada." International Journal of Environmental Studies 69, no. 2 (April 2012): 350–59. http://dx.doi.org/10.1080/00207233.2012.663228.

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Richardson, David B., and L. D. Danny Harvey. "Optimizing renewable energy, demand response and energy storage to replace conventional fuels in Ontario, Canada." Energy 93 (December 2015): 1447–55. http://dx.doi.org/10.1016/j.energy.2015.10.025.

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Lemieux, Alexander, Karen Sharp, and Alexi Shkarupin. "Preliminary assessment of underground hydrogen storage sites in Ontario, Canada." International Journal of Hydrogen Energy 44, no. 29 (June 2019): 15193–204. http://dx.doi.org/10.1016/j.ijhydene.2019.04.113.

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Shafeen, A., E. Croiset, P. L. Douglas, and I. Chatzis. "CO2 sequestration in Ontario, Canada. Part I: storage evaluation of potential reservoirs." Energy Conversion and Management 45, no. 17 (October 2004): 2645–59. http://dx.doi.org/10.1016/j.enconman.2003.12.003.

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Hwang, Pyeong-Ik, Seong-Chul Kwon, and Sang-Yun Yun. "Schedule-Based Operation Method Using Market Data for an Energy Storage System of a Customer in the Ontario Electricity Market." Energies 11, no. 10 (October 9, 2018): 2683. http://dx.doi.org/10.3390/en11102683.

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A new operation method for an energy storage system (ESS) was proposed to reduce the electricity charges of a customer paying the wholesale price and participating in the industrial conservation initiative (ICI) in the Ontario electricity market of Canada. Electricity charges were overviewed and classified into four components: fixed cost, electricity usage cost, peak demand cost, and Ontario peak contribution cost (OPCC). Additionally, the online market data provided by the independent electricity system operator (IESO), which operates the Ontario electricity market, were reviewed. From the reviews, it was identified that (1) the portion of the OPCC in the electricity charges increased continuously, and (2) large errors can sometimes exist in the forecasted data given by the IESO. In order to reflect these, a new schedule-based operation method for the ESS was proposed in this paper. In the proposed method, the operation schedule for the ESS is determined by solving an optimization problem to minimize the electricity charges, where the OPCC is considered and the online market data provided by the IESO is used. The active power reference for the ESS is then calculated from the scheduled output for the current time interval. To reflect the most recent market data, the operation schedule and the active power reference for the ESS are iteratively determined for every five minutes. In addition, in order to cope with the prediction errors, methods to correct the forecasted data for the current time interval and secure the energy reserve are presented. The results obtained from the case study and actual operation at the Penetanguishene microgrid test bed in Ontario are presented to validate the proposed method.
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Dissertations / Theses on the topic "Energy storage – Ontario"

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Rahman, Mohammed Nahid. "Energy Storage Solutions for Wind Generator Connected Distribution Systems in Rural Ontario." Thesis, 2009. http://hdl.handle.net/10012/4849.

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Environmental awareness and uncertainty about continued supply of fossil fuel has given rise to the renewable energy movement. Wind based power generation has been at the forefront of the motion to integrate distributed energy sources in the traditional power system. Due to various technical restrictions, wide scale penetration of wind generated power has been held back by most utilities. One such restriction is the variability of generation due to the technology’s dependence on Mother Nature. Energy storage devices can complement the wind generators by reducing this variability. These devices can store excess generation for supply during low generation periods. There are several promising technologies for both energy storage and power storage applications. Power storage devices provide short term fluctuation dampening capability while energy storage devices allow longer term storage. Pumped hydro, Vanadium Redox battery and Sodium-Sulphur battery are some of the viable energy storage technologies. This project provides a set of algorithms and guidelines to obtain the optimal configuration parameters of an energy storage device. To verify the efficiency of the algorithms, a model system has been obtained from a local utility. This system represents a typical radial distribution system in rural Ontario. The load demand, wind speed and energy prices for a period of one year have been obtained from utilities and Environment Canada. The main goal in determining the location of the storage device within a distribution system is to minimize the total cost of energy and the total energy loss during the period of analysis. Locating the storage device near the wind turbines or near the largest loads lead to the optimum results. Buses that are located near those elements can be considered as suitable locations for the storage device. The energy storage capacity and charge-discharge rate of the storage device are selected based on four criteria: maximize wind turbines’ load following capability, maximize capacity factors of the wind turbines, minimize system energy losses and minimize system energy costs. A weight based multi-objective optimization algorithm has been proposed to assign various priorities to these criteria and obtain a single solution. The larger the energy storage capacity of the storage device, the better the improvement in system performance. Lower charge-discharge ramp rates provide superior results. The parameters for storage device operating schedule, i.e. charge-discharge trigger levels, have been selected using similar criteria and weighted objective approach as for the capacity selection process. Higher charge trigger levels and moderate discharge trigger levels provide the optimum system performance. Once a set of parameters for the storage device has been selected, bus voltages over the period of study are analyzed. Voltage variations outside certain limits have been identified. Finally, a Monte Carlo based simulation approach is presented to obtain output parameter (system performance) variation ranges for pseudo random changes in input parameters.
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Books on the topic "Energy storage – Ontario"

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Energy, Ontario Ministry of. Natural gas storage in Ontario: Prepared for the Ontario Minsitry of Energy. [Toronto]: The Ministry, 1986.

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2

R, Perdue R., ed. Report of the board in the matter of an application under the Ontario Energy Board Act by Union Gas Limited for an extension to the Bickford Storage Pool. Toronto: Energy Board, 1986.

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Meeting, IEEE Industry Applications Society. Microprocessor control for motor drives and power converters: Presented October 3 at the 1993 IEEE Industry Applications Society Annual Meeting, Toronto, Ontario, Canada. 3rd ed. New York City: Institute of Electrical and Electronics Engineers, 1993.

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In the matter of the Ontario Energy Board Act and in the matter of applications by the Consumers Gas Company Ltd. for acquisition of shares of Tecumseh Gas Storage Limited and related assets from Imperial Oil Limited. [Toronto], Ont: The Board, 1991.

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Ontario. Energy Act: Revised Statutes of Ontario, 1990, chapter E.16 as amended by 1993, chapter 27, sched.; 1994, chapter 27, s. 81; 1996, chapter 19, s. 20 ; and, the following regulations (as amended) = Loi sur les hydrocarbures : Lois refondues de l'Ontario de 1990, chapitre E.16 tel qu'il est modifié par l'annexe du chap. 27 de 1993; l'art. 81 du chap. 27 de 1994; l'art. 20 du chap. 19 de 1996 ; et, les règlements suivants (tels qu'ils sont modifiés), Certificates (O. Reg. 348/96); Compressed natural gas storage, handling and utilization (O. Reg. 83/97); Fuel oil code (R.R.O. 1990, Reg. 329); Gas utilization code (O. Reg. 546/96); Oil and gas pipeline systems (O. Reg. 157/97); Propane storage, handling and utilization (O. Reg. 514/96). [Toronto]: Queen's Printer for Ontario = Imprimeur de la Reine pour l'Ontario, 2000.

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Conference papers on the topic "Energy storage – Ontario"

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Cooper, Thomas A., and James S. Wallace. "Design of a 200 kWe Solar Thermal Power Plant for Ontario." In ASME 2008 2nd International Conference on Energy Sustainability collocated with the Heat Transfer, Fluids Engineering, and 3rd Energy Nanotechnology Conferences. ASMEDC, 2008. http://dx.doi.org/10.1115/es2008-54216.

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A preliminary design and feasibility study has been conducted for a 200 kWe solar thermal power plant for operation in Ontario. The objective of this study is to assess the feasibility of small-scale commercial solar thermal power production in areas of relatively low insolation. The design has been developed for a convention centre site in Toronto, Ontario. The plant utilizes a portion of the large flat roof area of the convention centre to accommodate the collector array. Each power plant module provides a constant electrical output of 200 kWe throughout the year. The system is capable of maintaining the constant output during periods of low insolation, including night-time hours and cloudy periods, through a combination of thermal storage and a supplemental natural gas heat source. The powerplant utilized the organic Ranking cycle (ORC) to allow for relatively low source temperatures from the solar collector array. A computer simulation model was developed to determine the performance of the system year-round using the utilizability-solar fraction method. The ORC powerplant uses R245fa as the working fluid and operates at an overall efficiency of 11.1%. The collector is a non-concentrating evacuated tube type and operates at a temperature of 90°C with an average annual efficiency of 23.9%. The system is capable of achieving annual solar fractions of 0.686 to 0.874 with collector array areas ranging from 30 000 to 40 000 m2 and storage tank sizes ranging from 3.8 to 10 × 106L respectively. The lowest possible cost of producing electricity from the system is $0.393 CAD/kWh. The results of the study suggest that small-scale solar thermal plants are physically viable for year round operation in Ontario. The proposed system may be economically feasible given Ontario’s fixed purchase price of $0.42 CAD/kWh, but the cost of producing electricity from the system is highly dependent on the price of the solar collector.
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Abdelkader, Bassel A., and Mostafa H. Sharqawy. "Ecological Potential of Osmotic Power Generation by Pressure Retarded Osmosis in Ontario, Canada." In The 4th International Conference on Energy Harvesting, Storage, and Transfer. Avestia Publishing, 2020. http://dx.doi.org/10.11159/ehst20.114.

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Zaman, M. Hasanat, Ayhan Akinturk, and Andrew McGillis. "Simulation of Behaviour of an Energy Storage Device During Installation Process in Lake Ontario." In ASME 2018 37th International Conference on Ocean, Offshore and Arctic Engineering. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/omae2018-78508.

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A model of a compressed air energy storage unit is tested for tow-out and installation in the Ocean, Coastal & River Engineering (OCRE) Portfolio of the National Research Council of Canada (NRC). The proposed prototype accumulator is a cylinder of 36 m in diameter and 12 m in height, which will be installed at the bottom of Lake Ontario at about 60 m water depth. The model of the accumulator with scale 1:21.5 was fabricated at the Design and Fabrication Unit of NRC. Appropriate ballast systems were designed and applied for the tow out, installations and release mechanism tests. The model scale test was conducted to examine the hydrodynamic behavior of the accumulator during tow-out and set down operations. NRC’s Towing Tank and Offshore Engineering Basin test facilities were used for the tasks. In this paper only the installation case of the accumulator is reported and discussed. Relevant numerical simulations are also carried out. Comparisons of the numerical results with the experimental results show good agreement for the compared cases.
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Kadri, Abdeslem, and Farah Mohammadi. "Demand Charges Minimization for Ontario Class-A Customers Based on the Optimization of Energy Storage System." In 2020 IEEE Canadian Conference on Electrical and Computer Engineering (CCECE). IEEE, 2020. http://dx.doi.org/10.1109/ccece47787.2020.9255750.

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Omelianov, Vladimir, and Mohamed F. Abdel-Fattah. "Energy storage systems integration with household: A case study of average Ontario household using lead acid battery." In 2017 Saudi Arabia Smart Grid (SASG). IEEE, 2017. http://dx.doi.org/10.1109/sasg.2017.8356511.

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Fernandes, Thiago Ramos, and Bala Venkatesh. "Return on Investment Evaluation and Optimal Sizing of Behind-the-Meter Battery Energy Storage Systems in Large Commercial Buildings in Ontario." In 2022 IEEE Canadian Conference on Electrical and Computer Engineering (CCECE). IEEE, 2022. http://dx.doi.org/10.1109/ccece49351.2022.9918265.

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Yang, L., M. A. Douglas, J. Gusdorf, F. Szadkowski, E. Limouse, M. Manning, and M. Swinton. "Residential Total Energy System Testing at the Canadian Centre for Housing Technology." In ASME 2007 Power Conference. ASMEDC, 2007. http://dx.doi.org/10.1115/power2007-22137.

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This paper outlines a demonstration project planned and implemented at the Canadian Centre for Housing Technology (CCHT) in 2006. The CCHT, located on the campus of the National Research Council (NRC) in Ottawa, Ontario, Canada maintains two identical, detached, single-family houses that have the capacity to assess energy and building technologies in side by side comparisons with daily simulated occupancy effects. The paper describes the residential integrated total energy system being installed in one of the homes at the CCHT for this demonstration, consisting of two one-ton ground source heat pumps, an air handler with supplemental/back-up hydronic heating capability, a natural gas fired storage type water tank, an indirect domestic hot water storage tank and a multistage thermostat capable of controlling the system. There is also a description of the bore-field, consisting of three vertical wells arranged to suit a typical suburban landscape. Two of the wells serve the heat pumps; the third well is arranged between the other two to sink the waste heat from a cogeneration unit. The 6 kWe cogeneration unit to be installed in May 2007 is also described. The heat pump system was deliberately sized to satisfy the cooling load in Canada’s heat dominated climate, leaving room in the operation of the system to accept waste heat from the cogeneration unit, either directly or indirectly through recycling the heat through the ground to the heat pumps. This paper presents and discusses preliminary testing results during the fall of 2006 and modeling work of the ground heat exchanger component of the system and therefore sets the stage for performance modeling work that is currently underway at Natural Resources Canada (NRCan).
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Balatchev, Stefan. "Testing of an Oil-on-Water Sensing Technology for Detecting Pipeline Leaks in Remote Locations Subject to Freezing Conditions." In 2018 12th International Pipeline Conference. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/ipc2018-78624.

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This paper presents the results of the testing of an oil-on-water leak detection technology for isolated locations without power or communications infrastructure. A special attention was paid to the ability of the sensors to detect hydrocarbon leaks under freezing conditions, with thick ice formed on the surface of the water. A viable solution for remote locations and large water crossings needs ultra low-power solution and/or cyclic operation. The technology evaluated was a fully passive impedance polymer-absorption sensor (PAS) featuring “zero-power” consumption. This technology also provides an additional advantage, “an event memory”, and is perfectly suitable for cyclic operation for detecting moving oil stains. In October 2017 three polymer-absorption sensors of different lengths were placed in outdoor location in Ontario, Canada for long-term testing of reliability in freezing conditions. The sensors were connected to cellular modem for generating alerts. Another battery of three sensors of same lengths was installed in outdoor testing facility near Ottawa, ON, Canada and connected to real-time data acquisition equipment. A preliminary series of leak tests performed in October/November 2017 confirmed the initial assumptions of excellent sensitivity of the hydrocarbon oil-on-water detection based on polymer absorption. The average power consumption of the sensor excitation and its measurement frontend during the first two months of testing were found to be extremely low, a fraction of the power needed for the wireless modem itself. The leak tests were extended to oil under ice detection performed with 5 North-American crude oils and with 3 refined products from Mid-December 2017 to Mid-February 2018. The sensitivity, the sensor excitation/measurement front end power consumption, and the reliability of the sensors were assessed at freezing temperatures, with thickness of the ice comprised between 80 and 100 mm. The paper also presents the availability of stand-alone communication equipment suitable for integrating oil-on-water sensors, as well the energy harvesting or energy storage technologies for different climatic conditions.
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Khani, Hadi, Rajiv K. Varma, and Mohammad R. Dadash Zadeh. "Investigation of Ontario's electricity market behaviour and energy storage scheduling in the market based on model predictive control." In 2017 IEEE Power & Energy Society General Meeting (PESGM). IEEE, 2017. http://dx.doi.org/10.1109/pesgm.2017.8274023.

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Chu, Jenny, Cynthia A. Cruickshank, Wilkie Choi, and Stephen J. Harrison. "Modelling of an Indirect Solar-Assisted Heat Pump System for a High Performance Residential House." In ASME 2013 7th International Conference on Energy Sustainability collocated with the ASME 2013 Heat Transfer Summer Conference and the ASME 2013 11th International Conference on Fuel Cell Science, Engineering and Technology. American Society of Mechanical Engineers, 2013. http://dx.doi.org/10.1115/es2013-18222.

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Heat pumps are commonly used for residential space-heating and cooling. The combination of solar thermal and heat pump systems as a single solar-assisted heat pump (SAHP) system can significantly reduce residential energy consumption in Canada. As a part of Team Ontario’s efforts to develop a high performance house for the 2013 DOE Solar Decathlon Competition, an integrated mechanical system (IMS) consisting of a SAHP was investigated. The system is designed to provide domestic hot water, space-heating, space-cooling and dehumidification. The system included a cold and a hot thermal storage tank and a heat pump to move energy from the low temperature reservoir, to the hot. The solar thermal collectors supplies heat to the cold storage and operate at a higher efficiency due to the heat pump reducing the temperature of the collector working fluid. The combination of the heat pump and solar thermal collectors allows more heat to be harvested at a lower temperature, and then boosted to a suitable temperature for domestic use via the heat pump. The IMS and the building’s energy loads were modeled using the TRNSYS simulation software. A parametric study was conducted to optimize the control, sizing and configuration of the system. This paper provides an overview of the model and summarizes the results of the study. The simulation results suggested that the investigated system can achieve a free energy ratio of about 0.583 for a high performance house designed for the Ottawa climate.
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