地下水源热泵不同布井模式下地下温度场变化模拟分析

针对地下水源热泵抽水井与回灌井布局模式对地下温度场的影响,通过建立地下水流与温度的耦合模型,从抽灌井布置间距及抽灌井数量角度模拟分析了不同布井模式下地下水温度的变化趋势和热贯通发生的基本特性。结果表明,同类井间距对热贯通影响不显著,抽灌井间距对抽水温度及热贯通时间影响较大;从热贯通发生时间来看,抽灌井数量越多热贯通发生的时间越延迟,但从温度偏离度角度分析,系统长期运行后抽灌井数量对抽水温度偏离度影响不显著。     

某砾石回填抽灌同井地源热泵系统现场测试研究

为研究某砾石回填抽灌同井地源热泵系统的换热性能,利用多功能数据采集仪,对绵阳市某砾石回填抽灌同井地源热泵系统的夏季取冷进行了现场测试。结果表明:当抽水流量从14m~3/h降到8 m~3/h时,抽水温度从23.2℃降到17.9℃,抽回水温差从1.6℃上升到2.5℃,而热贯通系数由77.1%降到3.9%。可见,抽水流董的变化对砾石回填抽灌同井的影响很大,得出最佳抽水流量为8 m~3/h,此时换热董为23.3 kJ/h,热贯通系数为3.9%。     

冷热负荷失衡条件下采能区地温场的模拟研究

以北京某地下水源热泵空调系统为例,利用地下水、热耦合数值模型技术,对冷、热负荷严重不平衡条件下地下水抽灌场地温度场的年内和年际变化进行了定量模拟预测研究,并对系统长期运行的可行性进行了论证.研究结果表明:抽水井和回灌井之间的距离相对较大,抽灌井之间的"热突破"程度较低;由于空凋系统的供暖负荷显著大于制冷负荷,抽灌区温度场将呈逐年下降趋势;抽灌场地是一个开放的系统,不断与外界发生能量交换.随着热泵空调系统的长期运行,抽灌区的温度下降速率越来越小,地温场渐趋稳定;由于热泵系统的年内冷、热负荷存在严重失衡,进而对热泵系统的运行效率将产生一定影响.     

常温注水井对含水层热贯通的影响机理分析

为探究常温注水井对水源热泵热贯通现象的影响,利用FlowHeat1.0软件模拟了3组情景下含水层渗流场、温度场时空分布特征,并分析了常温注水井对含水层热贯通的影响机理和抽水井水温变化规律。结果表明,常温注水井通过减小回灌井、常温注水井之间的水力坡度和延长地下水渗透途径的方式达到缓解热贯通的效果;回灌井、常温注水井流量比相同时,常温注水井在抽灌井连线的位置对含水层热贯通的影响小;抽灌量不变时,常温注水井与回灌井的流量比越大,常温注水井缓解热贯通的效果越明显;在有利地下水回灌的水源热泵系统中,布设常温注水井能有效地降低含水层热贯通程度。     

基于CFD的填砾抽灌同井数值模拟

文章根据已有的填砾抽灌同井砂箱实验台,建立了两种不同尺寸的多区域耦合三维CFD模型,选取了热源井的抽水温度、逐时取热量和累计取热量进行模型验证。热源井抽水温度实验值与模拟值的吻合度较高,两种模型25 min内热源井累计取热量的相对误差分别为3.28%和5.56%。分析结果表明:砂箱的几何尺寸会对含水层流场和温度场的变化造成影响;回填砾石区会发生流贯通,中间隔断区的宽度与抽、回水区的间距会影响回水进入抽水区的速率,因此,应增大回水区与砂箱上顶板之间以及热源井与砂箱四壁之间的距离;应当增大中间隔断层的宽度以及抽、回水区的间距,以此来延缓流、热贯通的形成。     

R125/R290混合工质热泵制冷剂变流量特性研究

对混合工质R125/R290(25/75,质量配比)热泵变制冷剂流量特性进行了实验研究,并以55℃热汇出口温度为例,与被替代工质R134a和R22进行了对比分析。研究结果表明:随着制冷剂流量增大,排气温度线性下降,单位质量制热量则先上升后下降,系统COP随着制冷剂流量的增加表现为先线性增加后缓慢下降的趋势;在混合工质流量为1.12kg/min时,系统出现最大COP值3.040;系统火用效率则随着制冷剂质量流量的增大而增大。整个实验工况范围内,传热温差窄点一直保持在换热器中间部位。实验结果表明,在实验工况范围内,R125/R290(25/75)有望成为R134a及R22的替代工质。     

邯郸某社区空气源热泵供热系统性能仿真研究

以邯郸某社区住宅建筑为例,利用Trnsys软件搭建建筑模型和定流量、变流量空气源热泵供暖系统模型,模拟住宅全年建筑负荷变化情况,对比分析两种模型在同一工况下的机组制热量、系统性能指数SCOP变化情况,探究不同室内温度对机组制热量、SCOP的影响。结果显示:变流量模型的机组制热量低于定流量模型,但变流量模型的SCOP优于定流量模型;定流量模型中,随室内温度的增加,机组制热量涨幅较大但SCOP涨幅不大。结果为空气源热泵供暖系统的运行提供参考。     

地下水源热泵对井抽灌系统回灌能力研究

以西安市某水源热泵系统为例,建立对井抽灌渗流场模型,反演计算抽水过程与回灌过程的渗透系数,模拟分析含水层参数与井参数对热泵系统回灌能力的影响。结果表明:渗透系数是影响回灌能力的重要因素;相同含水层厚度条件下,应优先选择完整井地下水源热泵系统;减小抽灌井距对提高井的回灌能力效果不明显,但会提高发生热贯通的可能性;增大井径可减小抽水和回灌的压力,但会增加井的投资。回扬可显著提高回灌能力,越是回灌困难的系统,回扬效果越明显。     

一种带有热开关的新型温差发电系统

为解决工程应用中由于热源频繁波动造成温差发电系统性能严重下降的问题,提出一种带有热开关的新型温差发电系统。建立反映其动态特性的数学模型,并搭建能灵活投切热开关的温差发电原理性实验台。通过数值模拟和实验分析全面研究系统性能。结果表明,带热开关的温差发电系统可有效降低模块热端温度波动,提高系统输出功率和效率;同时,热开关的开启和关闭温度是影响系统性能的关键因素。     

盘式聚光系统吸热器热性能实验研究

该文研究设计制作了平顶锥形吸热器,安装在一部盘式聚光系统上,利用水作工质,进行了热性能实验研究.按照定流量、变流量及当地天气情况,测试了一段时间内吸热器进出口的温度变化,分析了吸热功率和热效率.实验显示,当太阳直射辐射的辐照度升高,不论是定流量还是变流量状态,吸热功率变化趋势相同(均增加);热效率变化趋势则不同,定流量状态下降低,变流量状态下升高.研究表明,利用盘式聚光系统通过吸热器对水进行加热,所涉及的太阳直射辐射辐照度和工质状态是影响盘式聚光系统吸热器的吸热功率和热效率的重要因素.以上研究,对太阳能中高温利用及实际研发一套盘式太阳能热发电系统有一定参考作用.     

Heating and cooling of a building by double hollow concrete slab

This paper presents the thermal performance, in the heating and cooling of a building, of a double hollow concrete slab, one of whose faces is exposed to solar radiation and ambient air while the other is in contact with room air at constant temperature. A blackwened network of pipes is laid on the top surface and glazed sutiably. the flow rate of water / air through pipes is kept constant. It is seen that there is a time difference of 10-12 h between the maximum/ minimum of the thermal flux extering the room and the solair temperature for any flow rate. the heat flux inside the room is reduced appreciably for higher infiltration when there is no water flow to heat the building. the effect of a water film on the performance of the wall/roof has also been discussed and found to be more effective for the reduction of the heat flux coming into the building.     

An investigation on the forced convection heat transfer in the gap of two rotating disks with laminar inflow

This study presents forced convection in the gap between two rotating disks with the laminar radial inward flow. The disk surfaces are held at a constant temperature different from the temperature of the fluid flowing. The disks' surfaces may also receive a heat flux. The temperature of the fluid flowing in the gap is predicted by solving the coupled equations of momentum, energy, and continuity in cylindrical coordinate numerically. The finite difference method is used to discretize the energy equation into nonlinear algebraic equations. The tridiagonal matrix algorithm is employed to solve the resulting algebraic equations. Predominantly, throughflow Reynolds number, rotational Reynolds number, gap ratio, speed ratio, and Peclet number are the parameters that affect the temperature distribution for the fixed disk temperature and for the heat flux boundary conditions. The Nusselt number compares reasonably well with the numerical results of other investigators. The heat flow into the fluid is higher for corotating disks than for contrarotating disks for both constant temperatures as well as heat flux boundary conditions. This is the first investigation that predicts temperature distribution due to forced convection in the gap of two rotating disks with laminar inflow.     

Numerical Investigation of Saturated Flow Boiling in Microchannels by the Lattice Boltzmann Method

Bubble formation in saturated flow boiling in 2D microchannels, generated from a microheater under constant wall heat flux or constant wall temperature conditions, is studied numerically based on a newly developed lattice Boltzmann model for liquid-vapor phase change. Simulations are carried out to study effects of inlet velocity, contact angle, and heater size on saturated flow boiling of water under constant wall heat flux conditions. Important information, such as effects of static contact angle on nucleation time and nucleation temperature, which was unable to be obtained by other numerical simulation methods, is obtained. Furthermore, effects of inlet velocity, contact angle, and superheat on nucleate boiling heat transfer in steady flow boiling of water under constant wall temperature conditions are also presented. It is found that the nucleate boiling heat transfer at the microheater is higher if the heater surface is more hydrophilic, because the superheated vapor at the hydrophilic wall has a thinner thermal boundary layer and a larger thermal conductivity.     

相变微胶囊悬浮液强制对流换热实验研究

提出了一种可以同时作为储能介质与传热流体的新型相变微胶囊悬浮液(MPCS),设计和搭建试验台,分别在层流和湍流条件下在等热流密度的光滑圆管中对MPCS进行了强制对流换热实验,研究了悬浮液浓度、流量、泵送功率和加热速率对其流动及传热特性的影响。结果表明:对于质量分数为5%的MPCS,当微胶囊中相变材料分别处于固体、固体-液体和液体状态时,对应的努塞尔数平均增大了23.9%、20.5%和9.1%;与纯水相比,MPCS作为在热力系统应用的传热流体可以实现强化传热,但是需要在传热实验中控制好相变过程才能使MPCS的传热性能优于水。     

Thermal and hydraulic performance of a modified two-stage evaporative cooler

The thermal and hydraulic performance of a modified two-stage evaporative cooler is evaluated. Variables considered are the mode of operation, packing thickness, mass flow rate of the water flowing to the precooler, and the mass flux of water flowing over the packing media. The effectiveness of the system increased with the increase of the mass flow rate of water flowing to the precooler, decreasing the mass flux of water flowing to the packing, and with the increase of the packing thickness. The effectiveness of the system with structured packing was higher than that with sheathy leaf base or natural fiber packing.The air-side pressure drop per unit length in the direction of air flow was nearly constant when the structured packing was used. For the sheathy leaf and natural fiber packings, the air pressure drop increased at a uniform rate as the mass flux of water flowing over the packing increased. The air pressure drop was lowest for the setup with the structured packing.     

基于分层蓄热水箱的相变球释热实验研究

相变蓄热水箱可有效调节集热器和负载端之间供求不匹配的矛盾,设计了环形布水器进水结构和蓄热水箱,并搭建相变蓄热水箱性能测试平台,对比直进型蓄热水箱和环形布水器蓄热水箱的温度分层,探究孔隙率、进水流速和变温进水等变量下相变蓄热水箱的热分层和相变球的释热性能。实验研究表明：环形布水器能有效抑制进水水流对温度场的扰动,保持良好的温度分层,使相变球逐层放热,增大相变球与传热流体（HTF）的温差,提高释热效率,保证高温水能够源源不断地提供给用户端;孔隙率越小分层效果越好;流速越大分层效果越差,但是释热效率有所提高;变温进水比恒温进水,释热时间延长约40%。     

具有变频泵的泵站经济运行方式研究

为了探究具有变频泵的泵站供水系统的经济运行方式,以单方水耗电量最低为优化目标,根据水泵运行时的能量公式,推导出全泵机组单方水耗电量随水泵效率和变频器效率变化的数学模型,以山西省某供水工程泵站为例,根据水泵、变频器两者效率随变速比变化的关系曲线,提出在原运行方式下改变泵站净扬程并适当提高变频泵的变速比的经济运行方式,计算和比较了水泵机组在经济运行方式与原运行方式下的单方水耗电量。结果表明,经济运行方式比原运行方式节能,可达到降低水泵机组能耗、实现泵站经济运行的目的。     

Temporal and spatial distribution of heat flux in oscillating flow subjected to an axial temperature gradient

The temporal and spatial distribution of heat flux within counter-oscillating slugs of fluid, along which is maintained a constant axial temperature gradient, is examined. It is found that the resultant axial heat flux pulsates at twice the base oscillation frequency and that the time-averaged axial heat flow under tuned conditions is orders of magnitude larger than that present in the absence of oscillations. Such thermal pumping is produced by the time-dependent interaction of a transverse conduction flux, produced by large transverse temperature gradients, with the periodic axial fluid motion.     

Numerical investigation on integrated thermal management for lithiumion battery pack with phase change material and liquid cooling

为满足3 C放电倍率下电池组散热要求,提出了PCM\液冷复合式散热方案,利用有限元分析了液体流速、流道排列方式、铝制框架鳍宽和环境温度对电池组温度的影响。结果表明,增加流速可优化电池组散热性能,但当流速大于0.08 m/s时,流速的增加对散热系统无明显优化;各流速下Type I散热方式效果均为最优且电池组满足散热要求;鳍宽为2 mm时可将电池组最高温度进一步降低1.6℃;当环境温度从38℃增至42℃时,复合式散热系统体现了良好的热稳定性能。     

Experimental investigation of a domestic solar water heater with solar collector coupled phase-change energy storage

Phase change materials (PCMs) have good properties such as high thermal capacity and constant phase change temperature. Their potential use in solar energy storage is promising. Tests of exposure and constant flow rate are performed to investigate the thermal performance of a domestic solar water heater with solar collector coupled phase-change energy storage (DSWHSCPHES). Due to the low thermal conductivity and high viscosity of PCM, heat transfer in the PCM module is repressed. The thermal performance of the DSWHSCPHES under exposure is inferior to that of traditional water-in-glass evacuated tube solar water heaters (TWGETSWH) with an identical collector area. DSWHSCPHES also performs more efficiently with a constant flow rate than under the condition of exposure. Radiation and initial water temperature have impacts on system performance; with the increase of proportion of diffuse to global radiation and/or initial water temperature, system performance deteriorates and vice versa.