Thermal Response Test by Improved Test Rig with Heating or Cooling Soil

An improved test rig providing both the heat and cold source was used to perform thermal response test(TRT), and the line source model was used for data analysis. The principle of determining the temperature difference between the inlet and outlet of test well can keep the heating or cooling rate constant, along with a reduced size of test rig. Among the influencial factors of the line source model, the temperature difference was determined as the most important, which agreed with the test results. When the gravel was taken as the backfill material, the soil thermal conductivities of heating and cooling at the test place were 1.883 W/(m·K) and 1.754 W/(m·K), respectively, and the deviation of TRT between heating and cooling soil was 6.8%. In the case of fine sand, the thermal conductivities of heating and cooling were 1.541 W/(m·K) and 1.486 W/(m·K), respectively, and the corresponding deviation was 6%. It was also concluded that different velocities of water had less influence on TRT than the temperature difference.

基于响应面模型的智能台架供风系统开发

为解决瞬态工况下,汽车主动进气格栅(AGS)开度及风扇转速实时调整,换热器进风量时刻改变,热管理测试台架风机无法实时为换热器提供精准瞬态供风这一问题,应用计算流体力学(CFD)仿真技术,分析了换热器进风量与车速、AGS开度及风扇转速之间的关系,并构建了数学模型,模型预测误差小于6.6%。将该模型置于CANOE设备中,与VN1640设备及风机系统连接,可实时采集车速、AGS开度及风扇转速CAN信号,计算换热器进风量,从而控制风机输出相应风量,实现了台架风机为换热器提供精准、实时供风这一目标。

基于实际工程的地埋管地源热泵回填材料导热性能差异分析

为研究实际工程应用中回填材料导热性能差异,以郑州市浅层地热能示范工程为研究对象,通过现场热响应试验、地温监测、数值模拟对中细砂、中细砂+水泥、中细砂+膨润土、原浆四种常见回填材料导热性能进行分析.研究结果表明:原浆的平均导热率最低为1.83 W/(m·℃),中细砂的平均导热率最大为2.17 W/(m·℃);同时中细砂排热和取热下单位深度换热量也为最大,分别为48.52 W/m和47.38 W/m.夏季制冷时中细砂+水泥材料温度仅升高0.0002℃,远低于中细砂材料温度升高;而冬季供暖时,四种材料的温度下降值相近,最小为4.2842℃.基于数值模拟结果,中细砂放热和吸热工况下热影响半径最小,为分别5.5 m和6 m;同时,岩土体温度增温速度由大到小为中细砂、原浆、中细砂+膨润土、中细砂+水泥.因此,中细砂导热性能最好,可作为研究区域地埋管地源热泵回填材料的首选.研究成果为场地条件相似地区地埋管地源热泵回填材料选择提供依据,并对推进郑州地区能源绿色低碳发展具有一定参考意义.

含重晶石粉回填料提升地埋管换热能力研究

为研究含重晶石粉回填料对平原区第四系和山区岩石地层钻孔地埋管换热能力的影响,开展了导热系数测试实验比对分析、现场热响应实验和长期运行条件的模拟计算。平原区第四系钻孔采用中砂回填,山区基岩钻孔采用水泥砂浆回填。室内导热系数测试发现:中砂回填料中重晶石粉质量分数为5%时,导热系数提升14.3%;水泥砂浆中添加5%的重晶石粉,导热系数提升7.3%。钻孔现场热响应测试发现:同一场地内夏季工况下,平原区含5%重晶石粉回填料钻孔地埋管延米换热量提高2.4 W/m,换热效率提升3.5%;山区内含5%重晶石粉水泥砂浆回填料钻孔地埋管延米换热量提高2.7 W/m,换热效率提升3.9%。经数值模拟计算,钻孔回填料重晶石粉质量分数提升至10%,地埋管延米换热能力提高约6.0%。总体上添加重晶石粉后地埋管换热能力得到提高且可持续性较好。

简化线热源对ATRT计算土体导热系数的影响——数值模拟研究

不同深度土体的导热系数是精细评价浅层地热能的关键参数,基于内加热光缆的热响应测试(ATRT)是获取原位土体分布式导热系数的有效方式之一。利用有限元数值模拟软件ComsolMultiphysics,建立了二维有限元多孔介质传热模型,探究了U型布设内加热光缆条件下内加热光缆间距对实施ATRT计算导热系数的影响。结果表明:ATRT的热响应过程可以分为3个阶段,分别是光缆影响阶段、回填料影响阶段和土体影响阶段。U型布设光缆会增加土体影响阶段达到稳定时的加热时间,不利于提高ATRT计算导热系数的效率;由于简化计算的影响,U型光缆测试结果计算所得的导热系数在加热初期出现了明显高于土体导热系数的峰值,随着加热时间的增加,U型光缆布设条件下温升速率逐渐接近理想线热源温升速率,计算结果也越接近于真实值,缩小间距可以加速这个过程;随着间距增大,将误差控制在10%以内的建议加热时间将快速增大,故在实际工况中为了提高测试效率应尽量减小U型光缆的布设间距。

EPC项目中地源热泵系统的设计优化与施工技术

浅层地热能是一种重要的新型能源,开发浅层地热能主要作用是为建筑物提供供暖制冷,目前利用浅层地热能作为冷、热源的地埋管地源热泵系统在工程中得到广泛应用。对芜湖某EPC公建项目地源热泵系统进行了研究,介绍了项目场地区域岩土热响应试验情况,根据相关规范要求进行了地埋管地源热泵系统的设计优化,阐述了地埋管地源热泵的施工技术。由岩土热响应试验得出芜湖地区适合做地源热泵系统,利用规范中热量平衡原理,优化了初步设计中地源热泵的数量和节点处理措施,缩短了施工工期并节省了工程造价,针对地源热泵施工过程中的技术难点提出应对措施,对工程实际具有参考意义。

基于叠加理论的柱热源模型岩土体热响应试验测试研究

岩土体热物性参数是计算浅层地热能资源量和进行地热能利用规划设计需要的重要参数,为获取岩土体热物性参数,本文基于叠加理论的柱热源模型,分析了换热孔内外相应的传热数学模型及数据拟合计算方法,以江苏省宿迁沭阳城区HRK1号孔为例,采用了恒定热流法试验测试,取得了现场热响应试验测试数据,采用基于叠加理论的柱热源数学模型对数据进行了拟合分析,分析结果表明,当埋管深度98.7 m,初始温度19.80℃,实际平均加热功率为3829 W,平均流量为1.30m^(3)/h(流速为0.68 m/s)时,岩土综合导热系数为2.32 W/(m·K),体积比热容为1.42×10^(3)J/(kg·K),换热孔内总热阻为0.125(m·K)/W。结果表明,基于叠加理论建立的柱热源模型处理现场热响应试验测试数据是可行的,可用于现场热物性测试数据的处理分析。

储能同轴深井换热器岩土热响应试验及换热性能分析

本文主要针对储能同轴深井换热器的换热性能问题,采用岩土热响应试验和数据分析方法进行了研究。在同轴深井换热器的基本结构和换热原理基础上,通过试验井的岩土热响应试验,获得了土壤初始平均温度和土壤热物性等实验数据,接着,文章进一步对换热器的换热能力进行了分析,包括释热工况、吸热工况以及换热能力分析。研究结果表明,本文提出的储能同轴深井换热器具有较高的换热性能,为今后同轴深井换热器的研究提供了有益的参考。

Thermal performance analysis of borehole size effect on geothermal heat exchanger

Thermal performance was the most important factor in the development of borehole heat exchanger utilizing geothermal energy.The thermal performance was affected by many different design parameters,such as configuration type and borehole size of geothermal heat exchanger.These eventually determined the operation and cost efficiency of the geothermal heat exchanger system.The main purpose of this work was to assess the thermal performance of geothermal heat exchanger with variation of borehole sizes and numbers of U-tubes inside a borehole.For this,a thermal response test rig was established with line-source theory.The thermal response test was performed with in-line variable input heat source.Effective thermal conductivity and thermal resistance were obtained from the measured data.From the measurement,the effective thermal conductivity is found to have similar values for twopair type(4 U-tubes)and three-pair type(6 U-tubes)borehole heat exchanger systems indicating similar heat transfer ability.Meanwhile,the thermal resistance shows lower value for the three-pair type compared to the two-pair type.Measured data based resistance have lower value compared to computed result from design programs.Overall comparison finds better thermal performance for the three-pair type,however,fluctuating temperature variation indicates complex flow behavior inside the borehole and requires further study on flow characteristics.

Characteristic analysis of bleeding effect on standing column well (SCW) type geothermal heat exchanger

Thermal performance is the most important factor in the development of a borehole heat exchanger utilizing geothermal energy.The thermal performance is affected by many different design parameters and different operating conditions such as bleeding.This eventually determines the operation and cost efficiency of the borehole heat exchanger system.The thermal performance of an open standing column well (SCW) type geothermal heat exchanger was assessed under the influence of bleeding.For this,a thermal response test rig was established with line-source theory.The test rig also had a bleeding function by releasing fluid while taking additional underground water through the heat exchanger.The thermal response test was performed with an additional constant input heat source.Effective thermal conductivity and thermal resistance were obtained from the measured data.From the measurement,the effective thermal conductivity is found to have 1.47 times higher value when bleeding is applied.The thermal resistance also increases by 1.58 times compared to a non-bleeding case.This trend indicates enhanced heat transfer in the SCW type heat exchanger with a bleeding function.Bleeding,therefore,could be an effective method of achieving a high heat transfer rate in the SCW type heat exchanger with sufficient underground water supply.

螺旋型能量桩热-力响应原位试验研究

针对单螺旋型、并联双螺旋型2种埋管形式能量桩在温度-荷载联合作用下开展现场原位试验,分析2种埋管形式能量桩的换热效率、桩体应变、桩体轴力、侧摩阻力等热力学变化规律。结果表明:并联双螺旋型能量桩升温时温度分布较单螺旋型能量桩更均匀,2根桩的换热功率分别稳定在9.44 kW和9.70 kW,桩体平均每延米瞬态热交换值分别为726.2 W/m和746.2 W/m;桩体最大和最小应变分别位于桩体中上部和桩端位置;升温过程中,桩侧摩阻力分布呈上负下正,中性点均位于桩体中上部;2根桩由升温产生的附加压应力分别达到7.29 kPa和6.33 kPa,由降温产生的附加拉应力分别达到-4.06 kPa和-4.75 kPa,单螺旋型能量桩由温度引起的下拉荷载比并联双螺旋型能量桩增加了885 kN,在实际工程中应给予重点关注。

砂土层占比对双U型地埋管换热器换热性能影响研究

以西安两处地源热泵项目为工程背景,基于恒热流线热源模型和斜率法,对双U型地埋管换热器(DUBTHE)开展现场岩土热响应试验(TRT),分析了砂土层占比、管径对DUBTHE换热性能的影响。结果表明:当砂层占比分别为16.71%,45.99%时,其岩土初始平均温度、综合导热系数分别为17.70℃,1.54 W/(m·K)和18.83℃,1.79 W/(m·K)|通过权重法计算的岩土综合导热系数是现场TRT测得的1.15~1.25倍;当砂层占比由16.71%增加到45.99%时,岩土初始平均温度和综合导热系数分别提高了6.38%和16.23%,并随着管径由25 mm增大到32 mm时,夏、冬季单位延米换热量分别提高了12.76%和35.61%|当砂层占比小于45%且地源热泵系统冷热负荷接近时,宜采用DN25 DUBTHE,当砂层占比大于45%且地源热泵系统热负荷大于冷负荷时,宜采用DN32 DUBTHE。

双U型地埋管换热器换热性能试验研究

双U型地埋管换热器(DUBTHE)在实际应用中易出现管路交叉,引起热短路,造成换热性能降低,直接影响浅层地源热泵系统的运行效率。以西安某浅层地源热泵项目为工程背景,基于无限长线热源理论和斜率法,通过现场岩土热响应试验、不同测温法测温试验,研究了岩土初始平均温度、导热系数和体积热容,及管卡间距对DUBTHE换热性能的影响。结果表明:多点式测温线缆测得的岩土初始平均温度为17.08℃,更接近实际地层温度。该地层的岩土综合导热系数和综合体积热容分别为1.65 W/(m·K)、2.81×10^(6 )J/(m^(3)·K)。DN25 DUBTHE的夏、冬季单位延米换热量随着管卡间距减小而增加,且增速随管卡间距的减小先增大后减小。当管卡间距分别为1、2、3、4 m时,DN25 DUBTHE的夏季单位延米换热量较无管卡分别提高了21.03%、19.48%、15.16%、3.92%;DN25 DUBTHE的冬季单位延米换热量较无管卡分别提高了20.83%、19.48%、14.94%、3.79%。工程中最优的管卡布置方式为2 m或3 m管卡间距的DN25 DUBTHE。研究结果可为关中地区浅层地源热泵系统的优化设计提供经验借鉴与数据支撑。

成都某综合交通枢纽浅层地源热泵地埋管热物性分析与系统评价

基于成都某综合交通枢纽南北场咽喉区开展地质勘察数据,并对其开展岩土热响应试验分析与评价。地勘结果表明,工程区地下水类型主要为基岩裂隙承压水,地下水的渗流作用加强了热量交换速率,使测试得到的岩土体的综合热换功率值偏大,地下水对地埋管式地源热泵系统的运行较为有利。工程区的岩土体双U平均导热系数平均值为:2.45~2.78W/(m·K),所在地的岩土体(深度110m内)初始平均温度为18.32℃。各试验孔中,双U形式的地埋管换热功率均大于单U形式的热换功率,换热功率提高约22%。从测试效果和经济角度出发,结合四孔联合测试工况,建议选用双U25地埋管,夏季标准工况释热能力为42.89W/m,冬季标准工况取热能力为-42.66W/m。全年动态负荷计算分析结果表明,站房部分由可再生能源提供的空调冷热负荷比例可达32.1%,枢纽部分由地源热泵系统提供的空调冷热负荷比例可达21.5%。该研究成果可为在轨道交通领域推进浅层地热能利用提供可靠的技术路线及理论依据。

地质条件及埋管形式对地埋管换热器换热性能影响研究

利用北京市35个现场换热孔岩土热响应试验数据,分析了地质条件和埋管形式对地埋管换热器换热性能的影响。研究结果表明地质条件对地埋管换热性能具有显著影响:地层初始平均温度每变化1℃,换热能力相差8%左右;基岩地层的地埋管换热能力平均比松散层高35%;换热孔处地下水流速从0.14 m/d增至0.91 m/d,Pe值从18增加至113,由于热对流换热作用加强,延米换热量提升13%。在相同地质条件下,套管式换热器冬季延米取热量比双U型换热器高约40%;换热深度从150 m增加至300 m时,双U型和套管式换热器延米取热量均略有升高。

某体育场馆地源热泵系统应用与节能分析

地源热泵系统是一种依赖地源的高效供能技术,因此做好地源参数的评估研究至关重要。采用岩土热响应试验的方法对地质条件、岩土热物性、换热孔的换热能力等参数进行了分析,为地源热泵系统实施的可行性论证、设计和施工提供依据。

合肥市第四系及红层岩土体热物性分布特征研究

实验室与现场热响应测试对比分析揭示了合肥市浅层200 m内第四系及红层岩土的热物性分布特征。结果表明,平均热导率由2.1 W/(m·K)升至2.8 W/(m·K),在西北部和东南部出现两处峰值区(2.8 W/(m·K)),体积热容由西北向东南逐渐增大,由2.1 MJ/(m^(3)·K)升至2.7 MJ/(m^(3)·K),其平面分布特征与地下水径流方向基本一致。岩土体的热导率平均值呈现出第四系(1.56 W/(m·K))<白垩系(1.69 W/(m·K))<古近系(2.02 W/(m·K))<侏罗系(2.46 W/(m·K)),体积热容平均值排列规律与热导率相反,呈现出侏罗系(2.10 MJ/(m^(3)·K))<古近系(2.27 MJ/(m^(3)·K))<第四系(2.36 MJ/(m^(3)·K))<白垩系(2.37 MJ/(m^(3)·K))。现场热响应试验结果相较于室内测试数据偏大,但更接近于实况。埋管类型采用双U型时岩土体综合导热系数要高出单U型埋管8%~15%,不同的换热孔口径致换热孔导热系数差异性很小(小于3%)。

Numerical simulation for thermal response test performance in closed-loop vertical ground heat exchanger

In this study, a series of numerical analyses was performed in order to evaluate the performance of full-scale closed-loop vertical ground heat exchangers constructed in Wonju, South Korea. The circulating HDPE pipe, borehole and surrounding ground formation were modeled using FLUENT, a finite-volume method (FVM) program, for analyzing the heat transfer process of the ground heat exchanger system. Two user-defined functions (UDFs) accounting for the difference in the temperature of the circulating inflow and outflow fluid and the variation of ground temperature with depth were adopted in the FLUENT modeling. The thermal conductivities of grouts (cement vs. bentonite) measured in laboratory were used as input values in the numerical analyses to compare the thermal efficiency of the cement and bentonite grouts used for installing the closed-loop vertical ground heat exchanger. A series of numerical analyses was carried out to simulate in-situ thermal response tests performed in the construction site. From the comparison between the in-situ thermal response test results and numerical simulations, the average thermal conductivity of the ground formation in the construction site is back-calculated as approximately 4 W/mK. This value can be used in evaluating the long-term performance of the closed-loop vertical ground heat ex changer.