Dynamic Simulation and Thermoeconomic Analysis of a Trigeneration System in a Hospital Application

Francesco Calise,Maria Vicidomini,Francesco Liberato Cappiello,Luigi Libertini,Massimo Dentice D’Accadia

doi:10.3390/en13143558

Francesco Calise, Maria Vicidomini + Show 3 more

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https://doi.org/10.3390/en13143558

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Journal: Energies	Publication Date: Jul 10, 2020
Citations: 11	License type: CC BY 4.0

Affiliation: University of Naples Federico II

Abstract

Hospitals are very attractive for Combined Heat and Power (CHP) applications, due to their high and continuous demand for electric and thermal energy. However, both design and control strategies of CHP systems are usually based on an empiric and very simplified approach, and this may lead to non-optimal solutions. The paper presents a novel approach based on the dynamic simulation of a trigeneration system to be installed in a hospital located in Puglia (South Italy), with around 600 beds, aiming to investigate the energy and economic performance of the system, for a given control strategy (electric-load tracking). The system includes a natural gas fired reciprocating engine (with a rated power of 2.0 MW), a single-stage LiBr-H2O absorption chiller (with a cooling capacity of around 770 kW), auxiliary gas-fired boilers and steam generators, electric chillers, cooling towers, heat exchangers, storage tanks and several additional components (pipes, valves, etc.). Suitable control strategies, including proportional–integral–derivative (PID) and ON/OFF controllers, were implemented to optimize the trigeneration performance. The model includes a detailed simulation of the main components of the system and a specific routine for evaluating the heating and cooling demand of the building, based on a 3-D model of the building envelope. All component models were validated against experimental data provided by the manufacturers. Energy and economic models were also included in the simulation tool, to calculate the thermoeconomic performance of the system. The results show an excellent economic performance of the trigeneration system, with a payback period equal to 1.5 years and a profitability index (ratio of the Net Present Value to the capital cost) equal to 3.88, also due to the significant contribution of the subsidies provided by the current Italian regulation for CHP systems (energy savings certificates).

Highlights

Cogeneration represents a mature and well-known technology, able to ensure remarkable energy and economic savings, due to the combined production of thermal end electric energy, from a single primary energy input [1,2]
In the case shown in the figure, Pel,Combined Heat and Power (CHP) is constantly equal to the power demand of the hospital (Pel,LOAD)
According to the operating strategy adopted for the system, it is able to constantly match the electric energy demand operating strategy adopted for the system, it is able to constantly match the electric energy demand of the hospital hospital

Summary

Introduction

Cogeneration (or CHP, Combined Heat and Power) represents a mature and well-known technology, able to ensure remarkable energy and economic savings, due to the combined production of thermal end electric energy, from a single primary energy input [1,2]. Trigeneration systems are CHP units whose thermal waste energy is used to drive a thermally-driven chiller. Such systems are often referred to as Combined Cooling, Heat and Power (CCHP) systems [3]. CHP and CCHP are based on the recovery of the exhaust heat rejected by an engine, called the prime mover (PM) [5]. Such thermal energy may be used for heating, process, production of sanitary hot water, etc., and/or to drive a thermally-driven chiller to produce cooling energy [1,6].

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