直膨式太阳能热泵热水器及其热经济性分析

介绍了直膨式太阳能辅助热泵热水器(DX-SAHPWH)的基本结构和工作原理.计算了直膨式太阳能辅助热泵热水器、空气源热泵热水器、太阳能热水器、电热水器和燃气热水器的运行能耗.分析了直膨式太阳能辅助热泵热水器的市场潜力、经济性以及社会效益.几种热水器比较结果表明,直膨式太阳能辅助热泵热水器能耗最小,运行费仅为电热水器的1/3,燃气热水器的1/2,空气源热泵热水器的415;与电热水器相比,使用直膨式太阳能辅助热泵热水器,户均年运行费可减少约1500元,2年左右即可回收额外的初投资.直膨式太阳能辅助热泵热水器与空气源热泵热水器的市场价格相当.由于其节能、环保、安全等,自身优势明显,预期该热水器应用前景广阔.     

太阳能水环路热泵性能分析

建立了非直膨式太阳能水环热泵的采暖季性能仿真模型,该模型包括热泵系统模型、蓄热水箱模型和集热器模型,根据此模型模拟分析了太阳能热泵在不同地区应用的性能系数.     

直膨式太阳能热泵系统性能分析及优化

直膨式太阳能热泵利用少量电能将太阳能的低品位能量转移至高品位,具有清洁、高效的优点,目前正成为节能领域的研究热点,近年来取得了飞速发展.国内外众多学者作了相关研究并取得了一定的成果.概述了直膨式太阳能热泵在国内外的研究进展,总结了内部参数和外部参数等方面对直膨式太阳能热泵系统性能的影响.针对不同的影响因素,给出了多种提高直膨式太阳能热泵系统性能的策略,以期对直膨式太阳能热泵的发展有一定的促进作用.     

直膨式太阳能热泵采暖蓄能制冷应用研究

以U型管式太阳集热器作为热泵系统的蒸发器,利用太阳能工程及传热学等热力学相关知识,对该直膨式太阳能热泵系统进行能效分析。论证结果表明:太阳集热器的综合效率达到90%以上,系统能效COP约3.53,同时以上海地区单户采暖为例,描述直膨式太阳能热泵采暖蓄能供冷系统的设计过程,该研究能够为太阳能热泵采暖及蓄能供冷的优化设计提供借鉴。     

直膨式太阳能热泵制热性能的对比研究

直膨式太阳能热泵(direct expansion solar assisted heat pump,DX-SAHP)可直接吸收利用太阳能,进而提高热泵的蒸发温度和性能系数(COP),有利于改善热泵的热性能和结霜。本文在带有太阳模拟发射器的焓差实验室中建立直膨式太阳能热泵和常规直彭热泵的对比实验,对不同条件下的热泵系统参数进行测量并进行性能对比和分析。实验结果显示,直膨式太阳能热泵能够吸收太阳能,在辐照度分别为100和200 W/m~2的工况下,系统制热功率比无辐照时的制热功率分别提高9.8%和21.8%,COP分别提高11.7%和23.7%,且除霜启动延迟23 min;辐照度为200 W/m~2时,直膨式太阳能热泵在环境温度5℃下的制热功率比1℃下的制热功率提高16.92%;在室外温度为1℃,相对湿度为95%的工况下,提高太阳辐照度,可有效减小涂层蒸发器进出口温度的波动,提高蒸发器运行的稳定性。此外,直膨式太阳能热泵在运行过程中吸收的太阳辐射被用来蒸发液态制冷剂工质,导致压缩机进气量增加,系统的制热功率和COP提高。     

直膨式太阳能热泵集热/蒸发器性能优化及其低温适应性研究

对直膨式太阳能热泵系统的集热/蒸发器结构进行优化,设计由六边形与四边形单元组合的流道结构,并进行仿真与实验研究。在上海地区,冬季工况下,将水温从10℃加热到50℃,系统COP可达到4.5;夏季工况下,将水温从30℃加热到55℃,系统COP可达到6.60。在此基础上,针对严寒地区冬季运行,研究了与喷气增焓循环耦合的低温型直膨式太阳能热泵系统。在环境温度为-10℃时,系统COP可达到3.79;环境温度为-20℃时,系统COP可达到3.69。依据实验与仿真数据,运用全生命周期经济性分析方法,以当量热价(LCoH)为评价指标,为太阳能热泵采暖经济性分析提供计算方法和理论依据。     

太阳能热泵多功能复合机监控系统设计与实验分析

鉴于直膨式太阳能热泵多功能复合机(DX-SAHPM)实验系统研究需要,该文给出了温度、压力、流量检测和热物理参数实时监控的PLC监控系统设计方案.该方案实现了太阳能热泵多功能复合机实验系统工况参数的自动检测、PID控制、监控与存储,并可根据系统实际检测需要进行必要的功能扩展(包括参数实时动态显示、热性能系数COP计算等),从而实现对被控量的智能控制.     

一种新型太阳能辅助高温热泵系统性能分析

为降低压缩机排气温度、优化热泵系统性能,设计了 一种利用太阳能集热器加热压缩机排气,利用蒸气显热制取高温热水的新型太阳能辅助热泵系统.结合天津地区的辐射日照条件对新型太阳能辅助热泵系统进行了可行性和热力性能分析,并将其与直膨式太阳能辅助热泵系统的性能进行对比.结果表明:该系统通过提高蒸发温度,可以降低制冷压缩机排气温度...     

专利信息

<正>太阳能热利用一种带有复合抛物面聚光器的直膨式太阳能热泵专利申请号:CN200810233401.6公开号:CN101363668申请人:云南师范大学本发明为一种带有复合抛物面聚光器的直膨式太阳能热泵。本发明的直膨式太阳能热泵是在现有太阳能热泵的基础上改进而成。它包括平板型太阳能集热器、节流阀、压缩机、储热水箱、冷     

太阳能热泵系统配置形式及其研究进展

采用不同用途及配置形式相结合的分类方法对太阳能热泵系统进行分类，指出不同形式太阳能热泵系统的特点、当前研究现状及未来发展趋势，分析环境及运行参数对系统热力性能的影响。通过文献综述发现，在一定运行工况下，直膨式太阳能热泵系统性能系数（COP）值可达9.40以上，非直膨式太阳能热泵系统COP值可达8.80以上。提出太阳能热泵系统的应用与研究应从能耗与效率、经济性、可靠性、运行与操控等方面着手，朝更加高效经济、节能可靠的方向发展。     

Experimental performance analysis on a direct-expansion solar-assisted heat pump water heater

A direct expansion solar assisted heat pump water heater (DX-SAHPWH) experimental set-up is introduced and analyzed. This DX-SAHPWH system mainly consists of 4.20 m² direct expansion type collector/evaporator, R-22 rotary-type hermetic compressor with rated input power 0.75 kW, 150 L water tank with immersed 60 m serpentine copper coil and external balance type thermostatic expansion valve. The experimental research under typical spring climate in Shanghai showed that the COP of the DX-SAHPWH system can reach 6.61 when the average temperature of 150 L water is heated from 13.4 °C to 50.5 °C in 94 min with average ambient temperature 20.6 °C and average solar radiation intensity 955 W/m². And the COP of the DX-SAHPWH system is 3.11 even if at a rainy night with average ambient temperature 17.1 °C. The seasonal average value of the COP and the collector efficiency was measured as 5.25 and 1.08, respectively. Through exergy analysis for each component of the DX-SAHPWH system, it can be calculated that the highest exergy loss occurs in the compressor, followed by collector/evaporator, condenser and expansion valve, respectively. Further more, some methods are suggested to improve the thermal performance of each component and the whole DX-SAHPWH system.     

Experimental performance analysis and optimization of a direct expansion solar-assisted heat pump water heater

In this study, a direct expansion solar-assisted heat pump water heater (DX-SAHPWH) with rated input power 750 W was tested and analyzed. Through experimental research in spring and thermodynamics analysis about the system performance, some suggestions for the system optimization are proposed. Then, a small-type DX-SAHPWH with rated input power 400 W was built, tested and analyzed. Through exergy analysis for each component of DX-SAHPWH (A) and (B), it can be seen that the highest exergy loss occurs in the compressor and collector/evaporator, followed by the condenser and expansion valve, respectively. Furthermore, some methods are suggested to improve the performance of each component, especially the collector/evaporator. A methodology for the design optimization of the collector/evaporator was introduced and applied. In order to maintain a proper matching between the heat pumping capacity of the compressor and the evaporative capacity of the collector/evaporator under widely varying ambient conditions, the electronic expansion valve and variable frequency compressor are suggested to be utilized for the DX-SAHPWH.     

Thermal performance analysis of a direct-expansion solar-assisted heat pump water heater

A direct-expansion solar-assisted heat pump water heater (DX-SAHPWH) is described, which can supply hot water for domestic use during the whole year. The system mainly employs a bare flat-plate collector/evaporator with a surface area of 4.2 m², an electrical rotary-type hermetic compressor, a hot water tank with the volume of 150 L and a thermostatic expansion valve. R-22 is used as working fluid in the system. A simulation model based on lumped and distributed parameter approach is developed to predict the thermal performance of the system. Given the structure parameters, meteorological parameters, time step and final water temperature, the numerical model can output operational parameters, such as heat capacity, system COP and collector efficiency. Comparisons between the simulation results and the experimental measurements show that the model is able to give satisfactory predictions. The effect of various parameters, including solar radiation, ambient temperature, wind speed and compressor speed, has been analyzed on the thermal performance of the system.     

Heat Loss Via Concrete Slab Floors With External Vertical Edge Insulations

Abstract

A new method was developed and validated against numerical simulations for the calculation of ground heat transfer via floors with vertical edge insulations along the external side of walls. Using the new method, heating and cooling energy demand for two typical houses in the eight capital cities of Australian state and territory were evaluated with different vertical edge insulations and full horizontal floor insulations. It was found that for tropical regions such as Darwin, both vertical edge and full horizontal floor insulation have no or little effect on house heating and cooling energy demand. In cooling dominated climates such as Brisbane, full horizontal floor insulation may increase the total heating and cooling energy demand due to the decoupling between the relatively cool ground and the rooms above. For heating dominated climates such as Melbourne, Canberra and Hobart, ground heat loss can contribute up to around half of the total house heating and cooling energy demand. Full horizontal floor insulation can be very effective in these heating dominated climates. For heating and cooling balanced climates such as Adelaide, Perth and Sydney, vertical edge insulation along the external side of the walls is more effective than full floor insulation.     

Dynamic model of counter flow air to air heat exchanger for comfort ventilation with condensation and frost formation

In cold climates heat recovery in the ventilation system is essential to reduce heating energy demand. Condensation and freezing occur often in efficient heat exchangers used in cold climates. To develop efficient heat exchangers and defrosting strategies for cold climates, heat and mass transfer must be calculated under conditions with condensation and freezing. This article presents a dynamic model of a counter flow air to air heat exchanger taking into account condensation and freezing and melting of ice. The model is implemented in Simulink and results are compared to measurements on a prototype heat exchanger for cold climates.     

Analyzing the effect of the longwave emissivity and solar reflectance of building envelopes on energy-saving in buildings in various climates

A dynamic computer simulation is carried out in the climates of 35 cities distributed around the world. The variation of the annual air-conditioning energy loads due to changes in the longwave emissivity and the solar reflectance of the building envelopes is studied to find the most appropriate exterior building finishes in various climates (including a tropical climate, a subtropical climate, a mountain plateau climate, a frigid-temperate climate and a temperate climate). Both the longwave emissivity and the solar reflectance are set from 0.1 to 0.9 with an interval of 0.1 in the simulation. The annual air-conditioning energy loads trends of each city are listed in a chart. The results show that both the longwave emissivity and the solar reflectance of building envelopes play significant roles in energy-saving for buildings. In tropical climates, the optical parameters of the building exterior surface affect the building energy-saving most significantly. In the mountain plateau climates and the subarctic climates, the impacts on energy-saving in buildings due to changes in the longwave emissivity and the solar reflectance are still considerable, but in the temperate continental climates and the temperate maritime climates, only limited effects are seen.     

An analysis of thermal and solar zone radiation models using an Angstrom–Prescott equation and artificial neural networks

The correlation between the clearness index and sunshine duration is useful in the estimation of the solar radiation for areas where measured solar radiation data are unavailable. Regression techniques and artificial neural networks were used to investigate the correlations between daily global solar radiation (GSR) and sunshine duration for different climates in China. Measurements made during the 30-year period (1971–2000) from 41 measuring stations covering 9 thermal and 7 solar climate zones and sub-zones across China were gathered and analysed. The performance of the regression and the ANN models in the thermal and solar zones was analysed and compared. The coefficient of determination (R²), Nash–Sutcliffe efficiency coefficient (NSEC), mean bias error (MBE) and root-mean-square error (RMSE) were determined. It was found that the regression models in both the thermal and the solar climate zones showed a strong correlation between the clearness index and sunshine duration (R²=0.79–88). There appeared to be an increasing trend of larger MBE and RMSE from colder climates in the north to warmer climates in the south. In terms of the thermal and solar climate zone models, there was very little to choose between the two models.     

Climatic influences on solar modelling in China

Correlation between clearness index and sunshine duration is useful to the estimation of the solar radiation for areas where measured solar radiation data are not available. Regression techniques were used to investigate the correlations between daily global solar radiation and sunshine duration for different climates in China. Measurements made during the 30-year period (1971–2000) from 40 measuring stations covering major thermal and solar climatic zones across China have been gathered and analysed. The correlations were developed for each individual station as well as for each of the major climates. It was found that the Angstrom–Prescott equation tended to give a good estimation of global solar radiation based on the corresponding measured sunshine hours. A simple two-parameter linear regression equation was proposed for each of the major thermal and solar climatic zones.     

Effect of solar absorptivity and emissivity of exterior surfaces on the thermal performance of a building

The effects of the solar absorptivity and the thermal emissivity of exterior building surfaces on the indoor air temperature of a one room building are evaluated in terms of the discomfort index. The thermal performance of the building has been investigated for four different climates prevalent in India, namely, composite (New Delhi), hot and dry (Jodhpur), cold and humid (Srinagar), and cold and dry (Leh). The results confirm the common-sense view that the building surface should have low solar absorptivity and high thermal emissivity in hot climates and high solar absorptivity and low thermal emissivity in cold climates for indoor thermal comfort conditions.     

Energy savings potential from improved building controls for the US commercial building sector

The US Department of Energy (DOE) sponsored a study to determine the national savings achievable in the commercial buildings through widespread deployment of controls, elimination of faults, and use of better sensing. The study estimated savings from 34 measures in 9 building types and across 16 climates. These buildings are responsible for almost 57% of the US commercial building sector energy consumption. In addition to the individual measures, three packages of measures were created to estimate savings: (1) efficient building, (2) typical building, and (3) inefficient building. The results showed significant potential for energy savings across all building types and climates. The total site potential savings by building type aggregated across all climates for each measure varied between 0 and 16%. The total site potential savings aggregated across all building types and climates for each measure varied between 0 and 11%. The national potential site energy savings across all building types studied is 29%. Across all building types, the savings represent approximately 1393 PJ (1.32 quads) of site energy savings or 2912 PJ (2.76 quads) of primary (or source) energy savings. Extrapolating the results for other building types not analyzed as part of this study, the primary energy savings could be in the range of 4220 to 5275 PJ. For comparison, the total US primary energy consumption across all sectors of energy use was 102,762 PJ (97.4 quads) in 2015. This makes commercial building control improvements strategically important to sustained reductions in national energy consumption. To realize most of this potential savings, many gaps can be addressed through research development and deployment (RD&D), as recommended in this paper.