Energy conservation in fruit dehydrators utilizing recirculation of exhaust air and heat recovery heat exchangers. Final report

This article draws on the experience matured while working with low-enthalpy geothermic installations both in the design and executive phase as well as ongoing monitoring, within the scope of energy conservation as it relates to building and construction. The goal is to illustrate the feasibility of adopting the ESBE certification protocol (Certification of Energy Efficient Low-Enthalpy Probes) aimed at optimizing the harnessing of local geothermic resources to satisfy the energy requirements of a building, measured against the initial investment. It is often the case, in fact, that during the course of a construction project for a given low-enthalpy installation, we verify incompa tibilities with the local geologic and geothermic models, which, if inadequate during construction, can compromise the proper functioning of the installation and its subsequent operation. To this end, the ESBE method, which adheres to the governing environmental regulations, and which takes its cue from technical statutes within the sector, permits us to validate via verification, simulations and tests, the geothermic field probes used in construction in an objective and standardized manner, thereby joining and supporting the most recent protocols for energy certification of buildings (LEED 2010, CASACLIMA 2011, UE 20120/31 Directive). ESBE certification operates through a dedicated Certifying Entity represented by the REET unit (Renewable Energies and Environmental Technologies) of FBK (Bruno Kessler Foundation) of Trento. The results obtained by applying the ESBE method to two concrete cases, relative to two complex geothermic systems, demonstrate how this protocol is able to guarantee, beyond the correct execution in the field of geothermic probes, an effective coverage of the energy requirements of the building during construction adopting the best optimization measures for the probes in keeping with the local geological and geothermic model.

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Simulation and Optimization of Combined Cycle Power Cycles Through HRSG’s Heat Exchangers Arrangement and Parameters for Exergy and Cost

Volume 6: Energy, Parts A and B ◽

10.1115/imece2012-86753 ◽

2012 ◽

Author(s):

Ravin G. Naik ◽

Chirayu M. Shah ◽

Arvind S. Mohite

Keyword(s):

Power Plant ◽

Steam Generator ◽

Heat Exchangers ◽

Heat Recovery ◽

Second Law Of Thermodynamics ◽

Combined Cycle ◽

Heat Recovery Steam Generator ◽

Exergetic Efficiency ◽

Power Cycles ◽

Combined Cycle Power Plant

To produce the power with higher overall efficiency and reasonable cost is ultimate aim for the power industries in the power deficient scenario. Though combined cycle power plant is most efficient way to produce the power in today’s world, rapidly increasing fuel prices motivates to define a strategy for cost-effective optimization of this system. The heat recovery steam generator is one of the equipment which is custom made for combined cycle power plant. So, here the particular interest is to optimize the combined power cycle performance through optimum design of heat recovery steam generator. The case of combined cycle power plant re-powered from the existing Rankine cycle based power plant is considered to be simulated and optimized. Various possible configuration and arrangements for heat recovery steam generator has been examined to produce the steam for steam turbine. Arrangement of heat exchangers of heat recovery steam generator is optimized for bottoming cycle’s power through what-if analysis. Steady state model has been developed using heat and mass balance equations for various subsystems to simulate the performance of combined power cycles. To evaluate the performance of combined power cycles and its subsystems in the view of second law of thermodynamics, exergy analysis has been performed and exergetic efficiency has been determined. Exergy concepts provide the deep insight into the losses through subsystems and actual performance. If the sole objective of optimization of heat recovery steam generator is to increase the exergetic efficiency or minimizing the exergy losses then it leads to the very high cost of power which is not acceptable. The exergo-economic analysis has been carried to find the cost flow from each subsystem involved to the combined power cycles. Thus the second law of thermodynamics combined with economics represents a very powerful tool for the systematic study and optimization of combined power cycles. Optimization studies have been carried out to evaluate the values of decision parameters of heat recovery steam generator for optimum exergetic efficiency and product cost. Genetic algorithm has been utilized for multi-objective optimization of this complex and nonlinear system. Pareto fronts generated by this study represent the set of best solutions and thus providing a support to the decision-making.

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Hysteresis in thermosyphon-based heat exchangers and introduction of a novel triggering system for low-temperature difference heat-recovery applications

Heat Recovery Systems and CHP ◽

10.1016/0890-4332(91)90054-8 ◽

1991 ◽

Vol 11 (6) ◽

pp. 523-531 ◽

Cited By ~ 8

Author(s):

T. Wadowski ◽

A. Akbarzadeh ◽

P. Johnson

Keyword(s):

Low Temperature ◽

Temperature Difference ◽

Heat Exchangers ◽

Heat Recovery

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Future trend of terminal energy conservation in steelmaking plant: Integration of molten slag heat recovery-combustible gas preparation from waste plastics and CO2 emission reduction

Energy ◽

10.1016/j.energy.2021.122543 ◽

2021 ◽

pp. 122543

Author(s):

Huining Zhang ◽

Jianping Dong ◽

Chao Wei ◽

Caifang Cao ◽

Zuotai Zhang

Keyword(s):

Energy Conservation ◽

Emission Reduction ◽

Co2 Emission ◽

Heat Recovery ◽

Molten Slag ◽

Future Trend ◽

Waste Plastics ◽

Co2 Emission Reduction ◽

Combustible Gas

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Possibilities of heat energy recovery from greywater systems

E3S Web of Conferences ◽

10.1051/e3sconf/20183003003 ◽

2018 ◽

Vol 30 ◽

pp. 03003 ◽

Cited By ~ 6

Author(s):

Kaja Niewitecka

Keyword(s):

Waste Water ◽

Heat Exchangers ◽

Heat Recovery ◽

Tap Water ◽

Residential Building ◽

Heat Energy ◽

Alternative Source ◽

Recovery System ◽

Heat Recovery System ◽

Sewage Systems

Waste water contains a large amount of heat energy which is irretrievably lost, so it is worth thinking about the possibilities of its recovery. It is estimated that in a residential building with full sanitary fittings, about 70% of the total tap water supplied is discharged as greywater and could be reused. The subject of the work is the opportunity to reuse waste water as an alternative source of heat for buildings. For this purpose, the design of heat exchangers used in the process of greywater heat recovery in indoor sewage systems, public buildings as well as in industrial plants has been reviewed. The possibility of recovering heat from waste water transported in outdoor sewage systems was also taken into consideration. An exemplary waste water heat recovery system was proposed, and the amount of heat that could be obtained using a greywater heat recovery system in a residential building was presented. The work shows that greywater heat recovery systems allow for significant savings in preheating hot tap water, and the rate of cost reimbursement depends on the purpose of the building and the type of installation. At the same time, the work shows that one should adjust the construction solutions of heat exchangers and indoor installations in buildings to the quality of the medium flowing, which is greywater.

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