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Difference between revisions of "Hybrid photovoltaic-trigeneration systems"

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* [[Simulations of Greenhouse Gas Emission Reductions from Low-Cost Hybrid Solar Photovoltaic and Cogeneration Systems for New Communities]]
 
* [[Simulations of Greenhouse Gas Emission Reductions from Low-Cost Hybrid Solar Photovoltaic and Cogeneration Systems for New Communities]]
 
* [[Performance of U.S. hybrid distributed energy systems: Solar photovoltaic, battery and combined heat and power]]
 
* [[Performance of U.S. hybrid distributed energy systems: Solar photovoltaic, battery and combined heat and power]]
*[[Emerging economic viability of grid defection in a northern climate using solar hybrid systems]]
+
* [[Emerging economic viability of grid defection in a northern climate using solar hybrid systems]]
 +
* [[The Potential for Grid Defection of Small and Medium Sized Enterprises Using Solar Photovoltaic, Battery and Generator Hybrid Systems]]
 
* [[Examining interconnection and net metering policy for distributed generation in the United States]]
 
* [[Examining interconnection and net metering policy for distributed generation in the United States]]
 
* [[Economic viability of captive off-grid solar photovoltaic and diesel hybrid energy systems for the Nigerian private sector]]
 
* [[Economic viability of captive off-grid solar photovoltaic and diesel hybrid energy systems for the Nigerian private sector]]
 
{{Solar navbox}}
 
{{Solar navbox}}

Latest revision as of 00:46, 10 December 2019


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Source[edit]

  • A.H. Nosrat, L.G. Swan, J.M. Pearce, "Improved Performance of Hybrid Photovoltaic-Trigeneration Systems Over Photovoltaic-Cogen Systems Including Effects of Battery Storage", Energy 49, pp. 366-374 (2013). DOI, open access.

Abstract[edit]

Recent work has proposed that hybridization of residential-scale cogeneration with roof-mounted solar PV (photovoltaic) arrays can increase the PV penetration level in ideal situations by a factor of five. In regions where there is a significant cooling load PV-cogen hybrid systems could be coupled to an absorption chiller to utilize waste heat from the cogen unit. In order to investigate realistic (non-ideal) loads that such a hybrid system would need to service, a new numerical simulation called PVTOM (PV-trigeneration optimization model) was created and coupled to the results of the established CHREM (Canadian Hybrid Residential End-Use Energy and Emissions Model). In this paper, PVTOM is applied to representative houses in select Canadian regions, which experience cooling loads, to assess the fuel utilization efficiency and reduction in greenhouse gas emissions from hybrid PV-cogen and trigen systems in comparison with conventional systems. Results of the optimization runs are provided and the efficacy of PV-cogen and PV-trigen systems is discussed. Both PV-trigen and PV-cogen systems have demonstrated to be more effective at reducing emissions when compared to the current combination of centralized power plants and household heating technologies in some regions.

Photovoltaic Trigeneration Hybrid System Design[edit]

Hybrid photovoltaic trigen system

Results of Simulations[edit]

Trigen-results.png

See Also[edit]