Portable Heat Pump Testing Device

Abstract The aim of this paper is to present the design and working principle of a portable testing device for heat pumps in the energy recirculation system. The presented test stand can be used for any refrigerating/reverse flow cycle device to calculate the device energy balance. The equipment is made of two portable containers of the capacity of 250 liters to simulate the air heat source and ground heat source with a system of temperature stabilization, compressor heat pump of the coefficient of performance (COP) of = 4.3, a failsafe system and a control and measurement system.

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Heat Pump Bridge Analysis Using the Modified Energy Transfer Diagram

Energies ◽

10.3390/en14010137 ◽

2020 ◽

Vol 14 (1) ◽

pp. 137

Author(s):

Florian Schlosser ◽

Heinrich Wiebe ◽

Timothy G. Walmsley ◽

Martin J. Atkins ◽

Michael R. W. Walmsley ◽

...

Keyword(s):

Energy Transfer ◽

Heat Pump ◽

Heat Recovery ◽

Heat Pumps ◽

Coefficient Of Performance ◽

Combined Application ◽

Recovery Potential ◽

Composite Curve ◽

And Performance ◽

The Individual

Heat pumps are the key technology to decarbonise thermal processes by upgrading industrial surplus heat using renewable electricity. Existing insight-based integration methods refer to the idealised Grand Composite Curve requiring the full exploitation of heat recovery potential but leave the question of how to deal with technical or economic limitations unanswered. In this work, a novel Heat Pump Bridge Analysis (HPBA) is introduced for practically targeting technical and economic heat pump potential by applying Coefficient of Performance curves into the Modified Energy Transfer Diagram (METD). Removing cross-Pinch violations and operating heat exchangers at minimum approach temperatures by combined application of Bridge Analysis increases the heat recovery rate and reduce the temperature lift to be pumped at the same time. The insight-based METD allows the individual matching of heat surpluses and deficits of individual streams with the capabilities and performance of different market-available heat pump concepts. For an illustrative example, the presented modifications based on HPBA increase the economically viable share of the technical heat pump potential from 61% to 79%.

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Factors Shaping A/W Heat Pumps CO₂ Emissions—Evidence from Poland

Energies ◽

10.3390/en14061576 ◽

2021 ◽

Vol 14 (6) ◽

pp. 1576

Author(s):

Piotr Jadwiszczak ◽

Jakub Jurasz ◽

Bartosz Kaźmierczak ◽

Elżbieta Niemierka ◽

Wandong Zheng

Keyword(s):

Air Quality ◽

Power System ◽

Heat Pump ◽

Heat Pumps ◽

Hot Water ◽

Coefficient Of Performance ◽

Conventional Heating ◽

Additional Stress ◽

The European Union ◽

Energy Mix

Heating and cooling sectors contribute to approximately 50% of energy consumption in the European Union. Considering the fact that heating is mostly based on fossil fuels, it is then evident that its decarbonization is one of the crucial tasks for achieving climate change prevention goals. At the same time, electricity sectors across the globe are undergoing a rapid transformation in order to accommodate the growing capacities of non-dispatchable solar and wind generators. One of the proposed solutions to achieve heating sector decarbonization and non-dispatchable generators power system integration is sector coupling, where heat pumps are perceived as a perfect fit. Air source heat pumps enable a rapid improvement in local air quality by replacing conventional heating sources, but at the same time, they put additional stress on the power system. The emissions associated with heat pump operation are a combination of power system energy mix, weather conditions and heat pump technology. Taking the above into consideration, this paper presents an approach to estimate which of the mentioned factors has the highest impact on heat pump emissions. Due to low air quality during the heating season, undergoing a power system transformation (with a relatively low share of renewables) in a case study located in Poland is considered. The results of the conducted analysis revealed that for a scenario where an air-to-water (A/W) heat pump is supposed to cover space and domestic hot water load, its CO2 emissions are shaped by country-specific energy mix (55.2%), heat pump technology (coefficient of performance) (33.9%) and, to a lesser extent, by changing climate (10.9%). The outcome of this paper can be used by policy makers in designing decarbonization strategies and funding distribution.

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Peak-Shaving Ratio Analysis of the Natural Gas Combined Heat and Power Plant With Distributed Peak-Shaving Heat Pumps

ASME 2017 11th International Conference on Energy Sustainability ◽

10.1115/es2017-3119 ◽

2017 ◽

Author(s):

Xiling Zhao ◽

Xiaoyin Wang ◽

Tao Sun

Keyword(s):

Natural Gas ◽

Heat Source ◽

Heat Pump ◽

Gas Turbines ◽

Heat Load ◽

Operating Cost ◽

Heat Pumps ◽

Optimized Design ◽

Peak Shaving ◽

Gas Price

Distributed peak-shaving heat pump technology is to use a heat pump to adjust the heat on the secondary network in a substation, with features of low initial investment, flexible adjustment, and high operating cost. The paper takes an example for the system that uses two 9F class gas turbines (back pressure steam) as the basic heat source and a distributed heat pump in the substation as the peak-shaving heat source. The peak-shaving ratio is defined as the ratio of the designed peak-shaving heat load and the designed total heat load. The economic annual cost is taken as a goal, and the optimal peak-shaving ratio of the system is investigated. The influence of natural gas price, electricity price, and transportation distance are also analyzed. It can provide the reference for the optimized design and operation of the system.

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Heat pump systems: A mini review

International Journal of Innovative Research and Scientific Studies ◽

10.53894/ijirss.v4i2.59 ◽

2021 ◽

Vol 4 (2) ◽

pp. 73-81

Author(s):

Mohammad Omar Temori ◽

František Vranay

Keyword(s):

Heat Pump ◽

Electricity Consumption ◽

Cost Savings ◽

Electrical Energy ◽

Primary Energy ◽

Heat Pumps ◽

Coefficient Of Performance ◽

Heating And Cooling ◽

Ground Source ◽

Reduce Electricity Consumption

In this work, a mini review of heat pumps is presented. The work is intended to introduce a technology that can be used to income energy from the natural environment and thus reduce electricity consumption for heating and cooling. A heat pump is a mechanical device that transfers heat from one environmental compartment to another, typically against a temperature gradient (i.e. from cool to hot). In order to do this, an energy input is required: this may be mechanical, electrical or thermal energy. In most modern heat pumps, electrical energy powers a compressor, which drives a compression - expansion cycle of refrigerant fluid between two heat exchanges: a cold evaporator and a warm condenser. The efficiency or coefficient of performance (COP), of a heat pump is defined as the thermal output divided by the primary energy (electricity) input. The COP decreases as the temperature difference between the cool heat source and the warm heat sink increases. An efficient ground source heat pump (GSHP) may achieve a COP of around 4. Heat pumps are ideal for exploiting low-temperature environmental heat sources: the air, surface waters or the ground. They can deliver significant environmental (CO2) and cost savings.

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Critical Analysis of Process Integration Options for Joule-Cycle and Conventional Heat Pumps

Energies ◽

10.3390/en13030635 ◽

2020 ◽

Vol 13 (3) ◽

pp. 635 ◽

Cited By ~ 1

Author(s):

Limei Gai ◽

Petar Sabev Varbanov ◽

Timothy Gordon Walmsley ◽

Jiří Jaromír Klemeš

Keyword(s):

Heat Pump ◽

Process Integration ◽

Waste Heat ◽

Correct Choice ◽

Heat Pumps ◽

Coefficient Of Performance ◽

Large Temperature ◽

Temperature Changes ◽

Application Range ◽

Source And Sink

To date, research on heat pumps (HP) has mainly focused on vapour compression heat pumps (VCHP), transcritical heat pumps (TCHP), absorption heat pumps, and their heat integration with processes. Few studies have considered the Joule cycle heat pump (JCHP), which raises several questions. What are the characteristics and specifics of these different heat pumps? How are they different when they integrate with the processes? For different processes, which heat pump is more appropriate? To address these questions, the performance and integration of different types of heat pumps with various processes have been studied through Pinch Methodology. The results show that different heat pumps have their own optimal application range. The new JCHP is suitable for processes in which the temperature changes of source and sink are both massive. The VCHP is more suitable for the source and sink temperatures, which are near-constant. The TCHP is more suitable for sources with small temperature changes and sinks with large temperature changes. This study develops an approach that provides guidance for the selection of heat pumps by applying Process Integration to various combinations of heat pump types and processes. It is shown that the correct choice of heat pump type for each application is of utmost importance, as the Coefficient of Performance can be improved by up to an order of magnitude. By recovering and upgrading process waste heat, heat pumps can save 15–78% of the hot utility depending on the specific process.

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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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Performance of Heat Pump Water Heater (HPWH) Systems and Their Impacts on Electric Utility Loads

Journal of Thermal Science and Engineering Applications ◽

10.1115/1.4002757 ◽

2010 ◽

Vol 2 (2) ◽

Author(s):

Yahya I. Sharaf-Eldeen

Keyword(s):

Heat Pump ◽

Energy Savings ◽

Electric Energy ◽

Cost Savings ◽

Electric Heating ◽

Electric Utility ◽

Heat Pumps ◽

Coefficient Of Performance ◽

Water Heaters ◽

Peak Loads

This work involves measurements, analyses, and evaluation of performance of air-source heat pump water heaters (HPWHs), and their impacts on electric utility loads. Two add-on, heat pumps (HPs) rated at 7000 BTU/h (2.051 kW) and 12,000 BTU/h (3.517 kW) were utilized. The HPs were retrofitted to two 50 gal (189.3 l) electric water heaters (EWHs) with their electric heating elements removed. A third standard EWH was used for comparison. The testing setups were fully instrumented for measurements of all pertinent parameters, including inlet and outlet water temperatures, inlet and outlet air temperatures of the HPs, temperature and humidity of the surrounding air, volume of water drawn out of the storage tanks, as well as the electric energy consumptions of the systems. Performance measures evaluated included the coefficient of performance, the energy factor (EF), and the first hour rating (FHR). The HPWH systems gave EFs ranging from 1.8 to 2.5 and corresponding energy savings (and reductions in utility peak loads) ranging from 49.0% to 63.0%, approximately. The values obtained in the summer months were, as expected, somewhat higher than those obtained in the winter ones. The average values of the EFs and energy savings (and reductions in utility peak loads) were about 2.1 and 56.0%, respectively. FHR results were much lower for the HPWHs compared with those for the standard EWH. These results show that HPWHs are much more efficient compared with standard EWHs. While the average value of the EF for the EWH was about 0.92, the HPWHs yielded EFs averaging more than 2.00, resulting in annual energy savings averaging more than 50%. The results also show that HPWHs are effective at reducing utility peak loads, in addition to providing substantial cost savings to consumers.

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Analysis of Regional Suitability of the Ground-Coupled Heat Pump Based on the Shallow Ground Thermal Balance

ASME 2009 3rd International Conference on Energy Sustainability, Volume 2 ◽

10.1115/es2009-90018 ◽

2009 ◽

Author(s):

Yuefen Gao ◽

Songling Wang ◽

Guoqiang Zhang

Keyword(s):

Heat Source ◽

Heat Pump ◽

Heat Pumps ◽

Scientific Application ◽

Term Operation ◽

Ground Heat Exchangers ◽

Ground Coupled Heat Pumps ◽

Ground Coupled Heat Pump ◽

Consistent Performance ◽

Source And Sink

Ground-coupled heat pump systems use the ground as a heat source and sink either with vertical or horizontal ground heat exchangers (GHXs) to supply heating in winter and cooling in summer. The ground heat source and sink has a near constant temperature, which is well suited to ground-coupled heat pumps, giving them consistent performance, regardless of the outdoor temperature. However, when the heat extracted from and rejected to the ground has great imbalance, the ground temperature will deviate from the original temperature with a long term operation. The deviation can reduce GHX performance greatly. As China has vast territory with variety climate, the annual cooling loads and heating loads are different at different places. And the imbalance between the extracted heat and the rejected heat also varies at different places. Therefore, it is necessary to analysis the regional suitability of the ground-coupled heat pump systems. The imbalance between the extracted heat and the rejected heat is analyzed by taking several typical cities in different climates. The new concepts of the Imbalance Ratio and the Extracted Heat to Rejected Heat Ratio are introduced as the weight factors to measure the imbalance in the ground. The values of the Imbalance Ratio and those of the Extracted Heat to the Rejected Heat Ratio are calculated. The optimum range of the Imbalance Ratio is recommended based on the vast investigation of the ground-coupled heat pumps. Some supplemental systems are put forward to supply heat in winter or to reject heat in summer at the places existing serious heat imbalance. The study is very meaningful to the scientific application of the ground-coupled heat pump systems in China.

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Comparison of Transcritical CO2 and Conventional Refrigerant Heat Pump Water Heaters for Domestic Applications

Energies ◽

10.3390/en12030479 ◽

2019 ◽

Vol 12 (3) ◽

pp. 479

Author(s):

Ignacio Paniagua ◽

Ángel Álvaro ◽

Javier Martín ◽

Celina Fernández ◽

Rafael Carlier

Keyword(s):

Heat Pump ◽

Thermodynamic Cycle ◽

Heat Pumps ◽

Design Tool ◽

Operating Conditions ◽

Hot Water ◽

Coefficient Of Performance ◽

Ambient Conditions ◽

Water Heater ◽

Water Heaters

Although CO 2 as refrigerant is well known for having the lowest global warming potential (GWP), and commercial domestic heat pump water heater systems exist, its long expected wide spread use has not fully unfolded. Indeed, CO 2 poses some technological difficulties with respect to conventional refrigerants, but currently, these difficulties have been largely overcome. Numerous studies show that CO 2 heat pump water heaters can improve the coefficient of performance (COP) of conventional ones in the given conditions. In this study, the performances of transcritical CO 2 and R410A heat pump water heaters were compared for an integrated nearly zero-energy building (NZEB) application. The thermodynamic cycle of two commercial systems were modelled integrating experimental data, and these models were then used to analyse both heat pumps receiving and producing hot water at equal temperatures, operating at the same ambient temperature. Within the range of operation of the system, it is unclear which would achieve the better COP, as it depends critically on the conditions of operation, which in turn depend on the ambient conditions and especially on the actual use of the water. Technology changes on each side of the line of equal performance conditions of operation (EPOC), a useful design tool developed in the study. The transcritical CO 2 is more sensitive to operating conditions, and thus offers greater flexibility to the designer, as it allows improving performance by optimising the global system design.

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Finite element modeling of geothermal source of heat pump in long-term operation

E3S Web of Conferences ◽

10.1051/e3sconf/202015404003 ◽

2020 ◽

Vol 154 ◽

pp. 04003

Author(s):

Elżbieta Hałaj

Keyword(s):

Finite Element ◽

Heat Source ◽

Heat Pump ◽

Heat Exchangers ◽

Transport Model ◽

Heat Pumps ◽

Initial Temperature Distribution ◽

Term Operation ◽

Borehole Heat Exchangers

Heat pumps become more and more popular heat source. They can be an alternative choice for obsolete coal fired boilers which are emissive and not ecological. During heat pump installation designing process, especially for heat pumps with higher heating capacity (for example those suppling larger buildings), a simulation of heat balance of ground heat source must be provided. A 3D heat transport model and groundwater flow in the geothermal heat source for heat pump (GSHP) installation was developed in FEFLOW according to Finite Element Modelling Method. The model consists of 25 borehole heat exchangers, arranged with spacing recommended by heat pump branch guidelines. The model consists of both a homogeneous, non-layered domain and a layered domain, which reflected differences in thermal properties of the ground and hydrogeological factors. The initial temperature distribution in the ground was simulating according to conditions typical for Europe in steady state heat flow. Optimal mesh refinement for nodes around borehole heat exchangers were calculated according to Nillert method. The aim of this work is to present influence of geological, hydrogeological factors and borehole arrangement in the energy balance and long term sustainability of the ground source. The thermal changes in the subsurface have been determined for a long term operation (30 years of operation period). Some thermal energy storage applications have also been considered.

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