The Reversed Brayton Cycle Heat Pump—A Natural Open Cycle for HVAC Applications

Using reasonable assumptions for turbomachinery efficiencies and heat exchanger effectivenesses, the Coefficient of Performance (COP) and Specific Heating Effect (SHE) of the regenerated and unregenerated cycles are computed and optimized. Only heating data are presented and both open and closed cycles are considered. An effort is made to indicate those cases where (the working fluid being air) the cycle may be appropriately open to combine the heating function with ventilation. When driven by an appropriately small direct Brayton cycle prime mover, the total potential for a new and widespread gas turbine application of literally millions of units becomes defined.

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Parametric Investigation of a Ground Source CO2 Heat Pump for Space Heating

Energies ◽

10.3390/en14123563 ◽

2021 ◽

Vol 14 (12) ◽

pp. 3563

Author(s):

Evangelos Bellos ◽

Christos Tzivanidis

Keyword(s):

Heat Exchanger ◽

Heat Pump ◽

Heat Pumps ◽

Geothermal Field ◽

Coefficient Of Performance ◽

Working Fluid ◽

Space Heating ◽

Geothermal System ◽

Parametric Investigation ◽

Ground Source

The objective of the present study is the parametric investigation of a ground source heat pump for space heating purposes with boreholes. The working fluid in the heat pump is CO2, and the geothermal field includes boreholes with vertical heat exchangers (U-tube). This study is conducted with a developed model in Engineering Equation Solver which is validated with data from the literature. Ten different parameters are investigated and more specifically five parameters about the heat pump cycle and five parameters for the geothermal unit. The heat pump’s examined parameters are the high pressure, the heat exchanger effectiveness, the temperature level in the heater outlet, the flow rate of the geothermal fluid in the evaporator and the heat exchanger thermal transmittance in the evaporator. The other examined parameters about the geothermal unit are the ground mean temperature, the grout thermal conductivity, the inner diameter of the U-tube, the number of the boreholes and the length of every borehole. In the nominal design, it is found that the system’s coefficient of performance is 4.175, the heating production is 10 kW, the electricity consumption is 2.625 kW, and the heat input from the geothermal field is 10.23 kW. The overall resistance of the borehole per length is 0.08211 mK/W, while there are 4 boreholes with borehole length at 50 m. The parametric analysis shows the influence of the ten examined parameters on the system’s performance and on the geothermal system characteristics. This work can be used as a reference study for the design and the investigation of future geothermal-driven CO2 heat pumps.

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Generalized Performance Characteristics of Refrigeration and Heat Pump Systems

Physics Research International ◽

10.1155/2010/341016 ◽

2010 ◽

Vol 2010 ◽

pp. 1-10 ◽

Cited By ~ 3

Author(s):

Mahmoud Huleihil ◽

Bjarne Andresen

Keyword(s):

Heat Pump ◽

Short Circuit ◽

Rankine Cycle ◽

Open Circuit ◽

Performance Characteristics ◽

Coefficient Of Performance ◽

Working Fluid ◽

Generic Model ◽

Brayton Cycle ◽

Transfer Rates

A finite-time generic model to describe the behavior of real refrigeration systems is discussed. The model accounts for finite heat transfer rates, heat leaks, and friction as different sources of dissipation. The performance characteristics are cast in terms of cooling rate (r) versus coefficient of performance (w). For comparison purposes, various types of refrigeration/heat pump systems are considered: the thermoelectric refrigerator, the reverse Brayton cycle, and the reverse Rankine cycle. Although the dissipation mechanisms are different (e.g., heat leak and Joule heating in the thermoelectric refrigerator, isentropic losses in the reverse Brayton cycle, and limits arising from the equation of state in the reverse Rankine cycle), the r−w characteristic curves have a general loop shape. There are four limiting types of operation: open circuit in which both r and w vanish in the limit of slow operation; short circuit in which again r and w vanish but in the limit of fast operation; maximum r; maximum w. The behavior of the considered systems is explained by means of the proposed model. The derived formulae could be used for a quick estimation of w and the temperatures of the working fluid at the hot and cold sides.

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Analysis of a Combined Cycle Plant Using a Small Particle Receiver to Drive a Primary Brayton Cycle

Volume 1: Advances in Solar Buildings and Conservation; Climate Control and the Environment; Alternate Fuels and Infrastructure; ARPA-E; Combined Energy Cycles, CHP, CCHP, and Smart Grids; Concentrating Solar Power; Economic, Environmental, and Policy Aspects of Alternate Energy; Geothermal Energy, Harvesting, Ocean Energy and Other Emerging Technologies; Hydrogen Energy Technologies; Low/Zero Emission Power Plants and Carbon Sequestration; Micro and Nano Technology Applications and Materials ◽

10.1115/es2015-49317 ◽

2015 ◽

Author(s):

Matthew Miguel Virgen ◽

Fletcher Miller

Keyword(s):

Heat Exchanger ◽

Gas Turbine ◽

Small Particle ◽

Power Plants ◽

Rankine Cycle ◽

Combined Cycle ◽

Working Fluid ◽

Brayton Cycle ◽

Efficiency Gains ◽

Steam Cycle

All current commercial CSP plants operate at relatively low thermodynamic efficiency due to lower temperatures than similar conventional plants and due to the fact that they all employ Rankine conversion cycles. We present here an investigation on the effects of adding a bottoming steam power cycle to a hybrid CSP plant based on a Small Particle Heat Exchange Receiver (SPHER) driving a gas turbine as the primary cycle. Due to the high operating temperature of the SPHER being considered (over 1000 Celsius), the exhaust air from the primary Brayton cycle still contains a tremendous amount of exergy. While in the previous analysis this fluid was only used in a recuperator to preheat the Brayton working fluid, the current analysis explores the potential power and efficiency gains from instead directing the exhaust fluid through a heat exchanger to power a Rankine steam cycle. Not only do we expect the efficiency of this model to be competitive with conventional power plants, but the water consumption per kilowatt-hour will also be reduced by nearly two thirds as compared to most existing concentrating solar thermal power plants as a benefit of having air as the primary working fluid, which eliminates the condensation step present in Rankine-cycle systems. Coupling a new steam cycle model with the gas-turbine CSP model previously developed at SDSU, a wide range of cases were run to explore options for maximizing both power and efficiency from the proposed CSP combined cycle gas turbine (CCGT) plant. Due to the generalized nature of the bottoming cycle modeling, and the varying nature of solar power, special consideration had to be given to the behavior of the heat exchanger and Rankine cycle in off-design scenarios. The trade-offs of removing the recuperator for preheating the primary fluid are compared to potential overall power and efficiency gains in the combined cycle case.

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Second Law Efficiency of an Intercooled-Reheated-Regenerative-Brayton Cycle With Variable Temperature Heat Reservoirs

ASME 2012 Gas Turbine India Conference ◽

10.1115/gtindia2012-9568 ◽

2012 ◽

Author(s):

Vishal Anand ◽

Krishna Nelanti ◽

Kamlesh G. Gujar

Keyword(s):

Gas Turbine ◽

Variable Temperature ◽

Pressure Ratio ◽

Working Fluid ◽

Thermodynamic Efficiency ◽

Second Law ◽

Brayton Cycle ◽

Cooling Fluid ◽

Turbine Engine ◽

Temperature Heat

The gas turbine engine works on the principle of the Brayton Cycle. One of the ways to improve the efficiency of the gas turbine is to make changes in the Brayton Cycle. In the present study, Brayton Cycle with intercooling, reheating and regeneration with variable temperature heat reservoirs is considered. Instead of the usual thermodynamic efficiency, the Second law efficiency, defined on the basis of lost work, has been taken as a parameter to study the deviation of the irreversible Brayton Cycle from the ideal cycle. The Second law efficiency of the Brayton Cycle has been found as a function of reheat and intercooling pressure ratios, total pressure ratio, intercooler, regenerator and reheater effectiveness, hot and cold side heat exchanger effectiveness, turbine and compressor efficiency and heating capacities of the heating fluid, the cooling fluid and the working fluid (air). The variation of the Second law efficiency with all these parameters has been presented. From the results, it can be seen that the Second law efficiency first increases and then decreases with increase in intercooling pressure ratio and increases with increase in reheating pressure ratio. The results show that the Second law efficiency is a very good indicator of the amount of irreversibility of the cycle.

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Performance Evaluation of a Vertical U-Tube Ground Heat Exchanger Using a Numerical Simulation Approach

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.724-725.909 ◽

2013 ◽

Vol 724-725 ◽

pp. 909-915

Author(s):

Ping Fang Hu ◽

Zhong Yi Yu ◽

Fei Lei ◽

Na Zhu ◽

Qi Ming Sun ◽

...

Keyword(s):

Heat Transfer ◽

Performance Evaluation ◽

Heat Exchanger ◽

Heat Pump ◽

Heat Transfer Process ◽

Working Fluid ◽

Outlet Temperature ◽

Ground Heat Exchanger ◽

Ground Source Heat Pump ◽

Ground Source

A vertical U-tube ground heat exchanger can be utilized to exchange heat with the soil in ground source heat pump systems. The outlet temperature of the working fluid through the U-tube not only accounts for heat transfer capacity of a ground heat exchanger, but also greatly affects the operational efficiency of heat pump units, which is an important characteristic parameter of heat transfer process. It is quantified by defining a thermal effectiveness coefficient. The performance evaluation is performed with a three dimensional numerical model using a finite volume technique. A dynamic simulation was conducted to analyze the thermal effectiveness as a function of soil thermal properties, backfill material properties, separation distance between the two tube legs, borehole depth and flow velocity of the working fluid. The influence of important characteristic parameters on the heat transfer performance of vertical U-tube ground heat exchangers is investigated, which may provide the references for the design of ground source heat pump systems in practice.

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A Small Scale Biomass Fueled Gas Turbine Engine

Volume 3: Coal, Biomass and Alternative Fuels; Combustion and Fuels; Oil and Gas Applications; Cycle Innovations ◽

10.1115/98-gt-315 ◽

1998 ◽

Author(s):

Joe D. Craig ◽

Carol R. Purvis

Keyword(s):

Gas Turbine ◽

Power Plants ◽

Small Scale ◽

Brayton Cycle ◽

Prime Mover ◽

Turbine Engine ◽

Rice Hulls ◽

Turbine Component ◽

The Cost ◽

New Generation

A new generation of small scale (less than 20 MWe) biomass fueled, power plants are being developed based on a gas turbine (Brayton cycle) prime mover. These power plants are expected to increase the efficiency and lower the cost of generating power from fuels such as wood. The new power plants are also expected to economically utilize annual plant growth materials (such as rice hulls, cotton gin trash, nut shells, and various straws, grasses, and animal manures) that are not normally considered as fuel for power plants. This paper summarizes the new power generation concept with emphasis on the engineering challenges presented by the gas turbine component.

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A Study on the Performance of a Cascade Heat Pump for Generating Hot Water

Energies ◽

10.3390/en12224313 ◽

2019 ◽

Vol 12 (22) ◽

pp. 4313 ◽

Cited By ~ 1

Author(s):

Boahen ◽

Choi

Keyword(s):

Heat Exchanger ◽

Energy Saving ◽

Heat Pump ◽

Heat Pumps ◽

Hot Water ◽

Research Interest ◽

Coefficient Of Performance ◽

Energy Saving Potential ◽

Heating Capacity

The use of cascade heat pumps for hot water generation has gained much attention in recent times. The big question that has attracted much research interest is how to enhance the performance and energy saving potential of these cascade heat pumps. This study therefore proposed a new cycle to enhance performance of the cascade heat pump by adopting an auxiliary heat exchanger (AHX) in desuperheater, heater and parallel positions at the low stage (LS) side. The new cascade cycle with AHX in desuperheater position was found to have better performance than that with AHX at heater and parallel positions. Compared to the conventional cycle, heating capacity and coefficient of performance (COP) of the new cascade cycle with AHX in desuperheater position increased up to 7.4% and 14.9% respectively.

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Experimental Study of Heating-Cooling Combined Ground Source Heat Pump System with Horizontal Ground Heat Exchanger

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.374-377.398 ◽

2011 ◽

Vol 374-377 ◽

pp. 398-404 ◽

Cited By ~ 1

Author(s):

Ying Ning Hu ◽

Ban Jun Peng ◽

Shan Shan Hu ◽

Jun Lin

Keyword(s):

Heat Exchanger ◽

Heat Exchange ◽

Heat Pump ◽

Hot Water ◽

Coefficient Of Performance ◽

Ground Heat Exchanger ◽

Pipe Length ◽

Pump System ◽

Heat Pump System ◽

Heating And Cooling

A hot-water and air-conditioning (HWAC) combined ground sourse heat pump(GSHP) system with horizontal ground heat exchanger self-designed and actualized was presented in this paper. The heat transfer performance for the heat exchanger of two different pipe arrangements, three layers and four layers, respectively, was compared. It showed that the heat exchange quantity per pipe length for the pipe arrangement of three layers and four layers are 18.0 W/m and 15.0 W/m. The coefficient of performance (COP) of unit and system could remain 4.8 and 4.2 as GSHP system for heating water, and the COP of heating and cooling combination are up to 8.5 and 7.5, respectively. The power consumption of hot-water in a whole year is 9.0 kwh/t. The economy and feasibility analysis on vertical and horizontal ground heat exchanger were made, which showed that the investment cost per heat exchange quantity of horizontal ground heat exchanger is 51.4% lower than that of the vertical ground heat exchanger, but the occupied area of the former is 7 times larger than the latter's.

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Frosting Phenomenon and Frost-Free Technology of Outdoor Air Heat Exchanger for an Air-Source Heat Pump System in China: An Analysis and Review

Energies ◽

10.3390/en11102642 ◽

2018 ◽

Vol 11 (10) ◽

pp. 2642 ◽

Cited By ~ 5

Author(s):

Yi Zhang ◽

Guanmin Zhang ◽

Aiqun Zhang ◽

Yinhan Jin ◽

Ruirui Ru ◽

...

Keyword(s):

Heat Exchanger ◽

Heat Pump ◽

Operating Cost ◽

Heating System ◽

Coefficient Of Performance ◽

Outdoor Air ◽

Pump System ◽

Heat Pump System ◽

Reduce Operating Cost ◽

Air Source Heat Pump

Frost layer on the outdoor air heat exchanger surface in an air-source heat pump (ASHP) can decrease the system coefficient of performance (COP). Although the common defrosting and anti-frosting methods can improve the COP, the periodic defrosting not only reduces the system energy efficiency but also deteriorates the indoor environment. To solve these problems, it is necessary to clearly understand the frosting phenomenon and to achieve the system frost-free operation. This paper focused firstly on the analyses of frosting pathways and frosting maps. Followed by summarizing the characteristics of frost-free technologies. And then the performances of two types of frost-free ASHP (FFASHP) systems were reviewed, and the exergy and economic analysis of a FFASHP heating system were carried out. Finally, the existing problems related to the FFASHP technologies were proposed. Results show that the existing frosting maps need to be further improved. The FFASHP systems can not only achieve continuous frost-free operation but reduce operating cost. And the total COP of the FFASHP heating system is approximately 30–64% higher than that of the conventional ASHP system under the same frosting conditions. However, the investment cost of the FFASHP system increases, and its reliability also needs further field test in a wider frosting environment. In the future, combined with a new frosting map, the control strategy for the FFASHP system should be optimized.

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Geothermal source heat pump performance for a greenhouse heating system: an experimental study

Journal of Agricultural Engineering ◽

10.4081/jae.2016.544 ◽

2016 ◽

Vol 47 (3) ◽

pp. 164-170 ◽

Cited By ~ 10

Author(s):

Alexandros Sotirios Anifantis ◽

Simone Pascuzzi ◽

Giacomo Scarascia-Mugnozza

Keyword(s):

Experimental Data ◽

Heat Pump ◽

Energy Demand ◽

Thermal Conditions ◽

Heating System ◽

Coefficient Of Performance ◽

Working Fluid ◽

Geothermal Heat ◽

Pump Performance ◽

Heating Energy Demand

Greenhouses play a significant function in the modern agriculture economy even if require great amount of energy for heating systems. An interesting solution to alleviate the energy costs and environmental problems may be represented by the use of geothermal energy. The aim of this paper, based on measured experimental data, such as the inside greenhouse temperature and the heat pump performance (input and output temperatures of the working fluid, electric consumption), was the evaluation of the suitability of low enthalpy geothermal heat sources for agricultural needs such as greenhouses heating. The study was carried out at the experimental farm of the University of Bari, where a greenhouse was arranged with a heating system connected to a ground-source heat pump (GSHP), which had to cover the thermal energy request. The experimental results of this survey highlight the capability of the geothermal heat source to ensue thermal conditions suitable for cultivation in greenhouses even if the compressor inside the heat pump have operated continuously in a fluctuating state without ever reaching the steady condition. Probably, to increase the performance of the heat pump and then its coefficient of performance within GSHP systems for heating greenhouses, it is important to analyse and maximise the power conductivity of the greenhouse heating system, before to design an expensive borehole ground exchanger. Nevertheless, according to the experimental data obtained, the GSHP systems are effective, efficient and environmental friendly and may be useful to supply the heating energy demand of greenhouses.

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