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1.
以中国南方亚热带地区典型的地下水补给型水库——大龙洞水库为对象,于2018年1月、4月、7月、10月、12月分别在上、中、下游三个监测点进行采样,探究水库热结构变化对于水体无机碳及其同位素的影响过程及机理。结果表明:(1)大龙洞水库水体在一个水文年中呈现周期性的混合期—分层期—混合期的热结构变化,4月热分层开始显现,7月逐渐显著呈现完整的热分层,10月以后热分层逐渐消失,水体逐渐实现混合;(2)水体热分层是溶解无机碳(DIC)浓度与碳稳定同位素(δ13CDIC)值变化的主要驱动力。表水层中DIC主要受水—气界面二氧化碳脱气、水生生物光合作用控制,其DIC浓度与δ13CDIC值分别为3.22 mmol·L?1和?9.15‰;温跃层中DIC主要受有机质降解过程影响,其DIC浓度与δ13CDIC值分别为3.43 mmol·L?1和?9.70‰;底水层中DIC主要受碳酸盐沉淀过程影响,其DIC浓度与δ13CDIC值分别为4.32 mmol·L?1和?11.89‰;(3)三种过程伴随水库热结构的变化而变化,驱动DIC浓度及其同位素的变化梯度 G (DIC)与 G (δ13CDIC)的变化,表现为底水层<表水层<温跃层。热分层结束进入混合期后,DIC浓度与δ13CDIC值的时空差异均逐渐消失,最终表现出DIC浓度与δ13CDIC值的均一化。 相似文献
2.
为探究季节性冰封浅湖热力学特征,于2010年10月至2013年7月对高原腹地一典型热融湖塘冰层生消、水/冰温及气象条件开展原位观测,分析了水温分布时间变化、温跃层以及冰生消对水温结构的影响。结果发现:冰面升华显著,贯穿整个冰期;水温日变化、季节变化和垂直结构受气温、大气辐射、风速、冰生消和湖底沉积层热贡献影响显著;在"无冰期-结冰前-冰生长期-冰融化期-融化后-无冰期"年循环过程中水温垂直结构分别呈现出"分层-翻转-逆温分层-逆温与正温共存-翻转-分层"的循环过程。分层期水温结构仅由上部混合层和温跃层构成,且偶因强风搅动而全湖翻转混合。可见,相比大中型湖泊,季节性冰封浅湖热力学结构差异显著。 相似文献
3.
根据2001年6月~2002年5月在天目湖进行的每月一次的全湖水温观测以及2002年5月25~26日在1号点的定点24h连续水温观测资料,分析研究了天目湖水温时空分布、垂直分布、温跃层的形成与变化以及湖泊热力学对溶解氧、营养盐的影响,揭示了各自的基本变化规律。结果表明:天目湖水温的日变化、年变化及垂直分布明显,而其水平差异不大;温跃层随着季节的变化而呈现增强-稳定-减弱-消失的周期变化;水温的变化以及温跃层的存在引起了水中溶解氧以及营养盐的变化。 相似文献
4.
为探究水电开发对大渡河水温过程的影响,采用原型观测和数学模型相结合的方法,对比分析了瀑布沟电站开发前后下游河道的水温时空变化特性。研究成果表明,与天然情况相比,现阶段瀑布沟下游沿程水温出现了明显的均化效应和延迟效应以及春夏季低温水、秋冬季高温水现象,最大降温2.4℃出现在4月的龚嘴尾水断面,最大升温3.3℃出现在12月的瀑布沟尾水断面;瀑布沟下游小型水库均未出现水温分层现象,但形成的蓄水体对沿程升温有一定的弱化,沿程增温率由天然状态的0.8℃/100 km降至现阶段的0.5℃/100 km;采用考虑了机械能转化的数学模型能较好地模拟瀑布沟下游河道的水温过程,率定得到的"机械能-内能"转化率为55%。 相似文献
5.
天然水体中存在同化二氧化碳(CO2)的光合作用,也存在释放CO2的微生物呼吸过程。地球表层水体与大气之间的CO2交换构成全球碳循环的一个重要环节。水-气之间CO2交换的方向和通量主要受大气圈和水体表层CO2分压(pCO2)的制约。水体pCO2值可以通过对近水面气体成分变化过程的现场仪器检测或者根据测定的水体化学参数运用经验公式计算求得。迄今对陆地水体,尤其河流筑坝形成的"蓄水河流"(下称水库)水体CO2动态研究中,由于水域及其近表层大气成分的时空多变,一般采用水化学参数计算方法求得水体的pCO2值。全球约70.97%的水库表层水体pCO2高于大气pCO2。全球尺度上水库表层水体pCO2自热带向寒温带逐渐递减;单个水库水体的pCO2一般呈现"出库>入库>库中"、pCO2随深度而增加的变化规律。水库表层水体pCO2的时间变化一般表现为"冬季>夏季、消融期>冰冻期、黑夜>白天"。水库水体的pCO2是其水化学平衡的结果,受水温、水体pH、水生生物活动以及外来水体的混合等多种因素影响,变化较为复杂。为精确量化水库水-气界面CO2交换通量,水文学、湖沼学、生态学和地球化学等领域的学者有必要合作,共同努力进行水库流域尺度的实地观测,完善水体溶解无机碳计算模型,深入探讨水库水体碳动力学机制,为全球碳循环研究和气候变化预测提供可靠的基础数据。 相似文献
6.
通过室内试验,研究了超固结比OCR对不同温度路径下中空圆柱饱和粉质黏土热固结特性的影响。研究表明,同一升温过程、不同超固结比试样所产生的最大孔压基本相同,但在相同的降温过程中,随着OCR的增大,产生的负孔压的绝对值有增大的趋势;升温或降温过程产生的体应变随着OCR的增大而减小,呈指数形式变化,并且温度幅度越大,这种变化幅度也越大;经过升温-降温过程后的最终体应变也随着OCR的增大而减小;升温或降温到同一温度值,其过程设置的温度等级越多,固结体应变也越大,并且随着OCR的增大,不同等级之间的体应变差值减小,而OCR对不同等级升温-降温后的最终体应变间的差值影响较小。 相似文献
7.
《地球科学进展》2016,(8)
通过2015年1月、4月、7月、10月水温、电导率、溶解氧、pH及叶绿素a监测数据对水体温度的季节动态及其垂直分层结构进行分析,探讨了泸沽湖水体水化学性质的季节性分层特征。结果表明:泸沽湖水体在春、夏、秋季出现明显的热力分层现象,冬季水温在垂向上接近同温状态,夏季温跃层位于10~25 m水深处,而秋季温跃层下移至20~30 m处。均温层水温维持在9.5~10℃与泸沽湖年均温一致,说明均温层水体稳定且处于相对恒温状态,是湖区年均温的反映。热力分层结构对电导率、溶解氧、pH及叶绿素a变化有一定影响,致使水体电导率、溶解氧、pH出现明显的分层现象,尤其在夏季,气温升高,热力分层现象显著,溶解氧和pH在温跃层内出现峰值,自峰值处向上、向下均呈递减趋势,均温层处于缺氧状态且p H值较小。虽然叶绿素a在温跃层以下维持较低水平,整体不高,但在表层有突然增高的现象,应予以高度警示,防止泸沽湖出现大面积藻类繁殖甚至局部性爆发。电导率垂向上呈递减变化,在温跃层内降低幅度较大。泸沽湖水体盐度基本保持恒定(约0.10‰),在不考虑盐度效应的情况下,无论是在垂直断面上还是在变温层、温跃层及均温层中,电导率与水温之间存在一简单线性函数关系,证明泸沽湖仍受自然气候影响,保持自然水体状态。 相似文献
8.
根据宜昌蒸发站历年实测资料分析得出,水面蒸发量随温度的变化可以分为升温期和降温期。各类型蒸发器(皿)的水面蒸发量与20m^2蒸发池的水面蒸发量的关系皆呈指数关系。所建立的经验公式使用简便、精度较高,是一种较好的换算方法。 相似文献
9.
《地球科学进展》2017,(6)
利用2015年4~9月对滇池从北到南4个部位的水体水温(Temperature或Temp)、溶解氧(DO)、pH值、叶绿素a(Chl-a)、藻蓝蛋白(Phycocyanin或PC)和电导率(Conductivity或CD)浓度等监测数据,分析了各参数从旱季向雨季转化以及雨季的特征和空间变化;通过表征蓝藻的藻蓝蛋白浓度和所有藻类的叶绿素浓度之比计算获得了水体中的蓝藻相对数量指数(Cyanophyte Relative Quantity Index,CRQI),并估算了蓝藻在湖泊中的相对数量。结果表明:滇池水温经4~5月增温后在6月达到最高值,之后7~9月在保持一定稳定性的背景下逐步降温,水体温度的变化过程不但会受到水深的影响,表现出在快速升温期不同部位升温速度不同、表层水温快的特点。实测数据分析发现,以叶绿素a值所代表的真核生物在4月快速增加并达到最大值,但以藻蓝蛋白所指示的蓝藻却在9月暴发,这与湖泊表层和底层水温一致、溶解氧含量丰富、pH值达最高并均一及水体盐度较低等因素直接相关。 相似文献
10.
水库的修建给防洪、发电、灌溉、供水等带来巨大经济效益的同时,也对环境产生一定的影响,尤其是水库泄流对下游河道水温的改变,扰乱下游动、植物繁殖与生长的自然节律,而梯级水库无疑将这一影响进行了放大。为研究水库梯级修建对水温的极限影响,构建了虚拟水库Alpha,并使Alpha水库首尾相连无限叠加,采用宽度平均的立面二维数学模型CE-QUAL-W2对梯级水库水温进行模拟。结果表明:河流梯级开发带来的水温累积影响存在极限,梯级开发使水温分层现象极大地弱化,但库区分层结构不会消失;经过22个梯级调节,水库下泄水温相对来流水温不再变化,在同一时刻、同一位置无论是表层水温还是库底水温均与上游梯级相同,库区流场也与上游流场相同;水库水温累积影响达到极限表明入流热量、出流热量完全达到平衡。 相似文献
11.
Abstract In order to study the thermal structure of active thrust belts, we have developed a numerical model of conductive heat transfer between thrust sheets during deformation. Our finite difference approach alternates small, instantaneous increments of displacement and isotherm translation with conductive relaxation of perturbed isotherms. In each step, conduction occurs for a length of time equal to the displacement increment divided by the thrust velocity. Computer simulations demonstrate that conductive heat transfer is significant during deformation and that temperatures in hanging-wall rocks decrease while temperatures in foot-wall rocks increase over distances of up to 10 km from the thrust surface. When the effects of internal heat production are also calculated, heating of foot-wall rocks exceeds cooling of hanging-wall rocks. Rocks located between two thrusts may experience a complicated temperature–time path of early heating followed by cooling. These models help to explain the rapid metamorphism of rocks in the Taconian thrust belt in the northern Appalachians of New England soon after deposition of the youngest sediments. 相似文献
12.
山东临沂地区古生代复合热储成矿模式研究 总被引:1,自引:0,他引:1
山东临沂地区地热资源丰富,前人对于临沂地区沂沭断裂带成热模式存在诸多争议。通过对研究区地热地质条件、地球物理特征和地热井数据进行综合研究,从地热产生的源、通、储、盖四要素进行分析,研究结果表明研究区地热成矿模式为古生代层状和带状复合热储地热成矿模式,断裂带为带状热储,断裂带周边稳定区域为层状热储。研究区热储为古生代砂岩,同时张性、张扭性断裂发育,导致热储为层状和带状的复合热储,较单一成因热储要复杂。对地热井数据归一化处理分析表明,盖层岩性及厚度对深部地热水温度存在较大影响,并且热储厚度对水温也存在影响,表现为表层有第四系覆盖的地热水温度,较无第四系覆盖的要高;盖层厚度越大,水温越高,热储厚度越大,水温也越高。这为进一步地热勘查与开采提供了理论指导。 相似文献
13.
基于CLM模式的青藏高原土壤冻融过程陆面特征研究 总被引:3,自引:3,他引:0
使用位于青藏高原东部若尔盖站的观测数据驱动CLM3.5模式,设计一组去除模式中冻融过程的"退化试验",进行为期一年的模拟研究。通过对比原试验与敏感性试验模拟结果,初步分析冻融过程在土壤温度变化、各能量通量分配中的作用,得到以下结论:(1)冻融过程是土壤温度变化的"缓冲器",冻结过程向周围环境释放能量减缓了土壤降温的速率,使土壤温度不至降得太低,而消融过程从周围环境吸收能量减缓了土壤升温的速率,使土壤温度不至升高太多;(2)冻融过程改变了地表辐射通量,土壤冻结改变了地表反照率,改变了向上短波辐射,且由于冻结过程减缓了地表温度的下降,改变了地表向上长波辐射,进而改变了净辐射通量;(3)冻融过程显著地改变了陆面能量的分配,通过相变能量的释放和吸收增大了地气间能量的传输,显著地增大了地表土壤热通量,且通过改变地表温度和地表蒸发,改变了感热及潜热通量。在冻结过程及完全冻结阶段,感热及潜热通量均增大,但在消融过程阶段,感热及潜热通量均减小。冻融过程对土壤热通量及感热通量的影响在冻结过程及完全冻结阶段更为显著,而对潜热的影响则是在消融过程阶段更为显著。 相似文献
14.
Seepage-heat transfer coupling process of low temperature return water injected into geothermal reservoir in carbonate rocks in Xian County,China 
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下载免费PDF全文 WANG Yan LIU Yan-guang BIAN Kai ZHANG Hong-liang QIN Shen-jun WANG Xiao-jun 《地下水科学与工程》2020,8(4):305-314
Fracture seepage and heat transfer in the geothermal reservoir of carbonate rocks after the reinjection of low temperature geothermal return water is a complex coupling process,which is also the frontier of geothermal production and reinjection research. Based on the research of cascade comprehensive development of geothermal resources in Beijing-Tianjin-Hebei (Xian County),the carbonate geothermal reservoir of Wumishan formation in the geothermal field in Xian County is investigated. With the development of the discrete fracture network model and the coupling model of seepage and heat transfer,the numerical solution of seepage field and temperature field with known fracture network is reached using the finite element software COMSOL,and the coupling process of seepage flow and heat in carbonate rocks is revealed. The results show that the distribution of temperature field of fractured rocks in geothermal reservoir of carbonate rocks has strong non-uniformity and anisotropy. The fracture network is interpenetrated,which constitutes the dominant channel of water conduction,and along which the fissure water moves rapidly. Under the influence of convective heat transfer and conductive heat transfer,one of the main factors to be considered in the study of thermal breakthrough is to make the cold front move forward rapidly. When the reinjection and production process continues for a long time and the temperature of the geothermal reservoir on the pumping side drops to a low level,the temperature of bedrocks is still relatively high and continues to supply heat to the fissure water,so that the temperature of the thermal reservoir on the pumping side will not decrease rapidly to the water temperature at the inlet of reinjection,but will gradually decrease after a long period of time,showing an obvious long tail effect. The distribution of fractures will affect the process of seepage and heat transfer in carbonate reservoirs,which should be considered in the study of fluid thermal coupling in carbonate reservoirs. 相似文献
15.
Numerical modeling of water infiltration in slopes under rainfall conditions, especially under rainstorm conditions, is a fundamental problem for slope stability assessment. To obtain representative results, surface water–groundwater flow models are incorporated in the simulation. Based on finite element representation of Richards’ equation and of kinematic wave equations, an integrated 2D numerical model (IMCR2D) of the surface water–groundwater system was established. The model has a symmetrical matrix that modifies the flux boundary according to the runoff solution on the slope. IMCR2D was verified using two laboratory experiments, and it showed good agreement with numerical and experimental results. Additional numerical examples were used to study the effect of flux supply from runoff on infiltration. In comparison with SimMd (an existing method), IMCR2D displayed advantages in cases where surface runoff develops in an upper low-permeability section of the slope and flows down into a high-permeability section of the slope. To illustrate the advantages of the new method, the seepage field and stability condition of a case study in the Three Gorges Hydroelectric Reservoir were analyzed using IMCR2D and SimMd. The deformation of a landslide in part reflects its stability, and therefore, we also used displacement monitoring data to estimate the variation of stability conditions from that aspect. Comparison of the two numerical models indicated that flux supply greatly affects the seepage field, and that rainfall plays an important role in landslide stability evaluation, but only when considering flux supply from upper slope surface runoff. 相似文献
16.
在次级冻胀现象中,对处于已冻土和未冻土之间的冻结缘地带,研究其中的水分迁移是一个重要的课题.在已建立的次级冻胀数学模型的基础上,通过假设有行波解的存在,建立了一组新的方程和边界条件,就冰分凝和冻渗两种情况进行了讨论,并以试验数据为例,模拟了开放系统饱水土的入流量历时曲线. 相似文献
17.
W. C. Liu W. B. Chen 《International Journal of Environmental Science and Technology》2013,10(2):251-260
This article presents the modeling of hydrothermal characteristics and suspended solids in a long and large-volume reservoir with a highly fluctuating water level. A laterally averaged two-dimensional hydrothermal and water quality model was configured for the Shihmen Reservoir in northern Taiwan. The model was validated with measured data of water surface elevation, water temperature, and concentration of suspended solids in 2006. The results show that the numerical model was able to reproduce the measured data. The validated model was then used to investigate the effects of water withdrawal schemes at different depths and to estimate the residence time in the reservoir. When water is withdrawn from a great depth, the relatively warm water from the upper layers can replace that in the deep layers, thereby facilitating heat transfer from the surface to the deeper layer. Bottom-water withdrawal results in a lower concentration of suspended solids compared with withdrawal from depths of 20 and 40 m. The simulated results show that the residence time is approximately 154 days in the Shihmen Reservoir. 相似文献
18.
In this study, soil volumetric water content and temperature variations are analyzed in an embankment constructed at Héricourt in France. A fully coupled hydro-thermal soil model is developed allowing two dimensional analysis. With meteorological data, soil surface heat flux and water flux boundary conditions are estimated considering soil-atmosphere interaction. Comparisons between measurements and simulations reveal the relevance of the proposed approach, in particular in terms of suitable boundary conditions and soil parameters. Both field monitoring and numerical modeling indicate that the influence depth of soil-atmosphere interaction is limited for volumetric water content, but it is much greater for temperature. 相似文献
19.
《Applied Geochemistry》2006,21(7):1184-1203
This paper examines the seasonal cycling of temperature and salinity in Dexter pit lake in arid northern Nevada, and describes an approach for modeling the physical processes that operate in such systems. The pit lake contains about 596,200 m3 of dilute, near neutral (pHs 6.7–9) water. Profiles of temperature, conductivity, and selected element concentrations were measured almost monthly during 1999 and 2000. In winter (January–March), the pit lake was covered with ice and bottom water was warmer (5.3 °C) with higher total dissolved solids (0.298 g/L) than overlying water (3.96 °C and 0.241 g/L), suggesting inflow of warm (11.7 °C) groundwater with a higher conductivity than the lake (657 versus 126–383 μS/cm). Seasonal surface inflow due to spring snowmelt resulted in lower conductivity in the surface water (232–247 μS/cm) relative to deeper water (315–318 μS/cm). The pit lake was thermally stratified from late spring through early fall, and the water column turned over in late November (2000) or early December (1999). The pit lake is a mixture of inflowing surface water and groundwater that has subsequently been evapoconcentrated in the arid environment. Linear relationships between conductivity and major and some minor (B, Li, Sr, and U) ions indicate conservative mixing for these elements.Similar changes in the elevations of the pit lake surface and nearby groundwater wells during the year suggest that the pit lake is a flow-through system. This observation and geochemical information were used to configure an one-dimensional hydrodynamics model (Dynamic Reservoir Simulation Model or DYRESM) that predicts seasonal changes in temperature and salinity based on the interplay of physical processes, including heating and cooling (solar insolation, long and short wave radiation, latent, and sensible heat), hydrologic flow (inflow and outflow by surface and ground water, pumping, evaporation, and precipitation), and transfers of momentum (wind stirring, convective overturn, shear, and eddy diffusion). Inputs to the model include the size and shape of the lake, daily meteorological data (short wave radiation, long wave radiation or cloud cover, air temperature, vapor pressure, wind speed, and rainfall), rates for water inputs and outputs, the composition of inflowing water, and initial profiles of temperature and salinity. Predicted temperature profiles, which are influenced by seasonal changes in the magnitude of solar radiation, are in good agreement with observations and show the development of a strong thermocline in the summer, erosion of the thermocline during early fall, and turnover in late fall. Predicted salinity profiles are in reasonable agreement with observations and are affected by the hydrologic balance, particularly inflow of surface and groundwater and, to a lesser degree, evaporation. Defining the hydrodynamics model for Dexter pit lake is the first step in using a coupled physical – biogeochemical model (Dynamic Reservoir Simulation Model-Computational Aquatic Ecosystem Dynamics Model or DYRESM-CAEDYM) to predict the behavior of non-conservative elements (e.g., dissolved O2, Mn, and Fe) and their effect on water quality in this system. 相似文献
20.
高温地热系统中赋存着大量的地热能资源.为了进一步了解高温地热系统, 以腾冲热海热田为典型研究区, 利用热泉地球化学组成, 基于多种地球化学模型确定了热田深部母地热流体的温度, 并分析了其升流后经历的不同冷却过程.热海热田的硫磺塘水热区和热水塘水热区所排泄的热泉源自共同的深部热储, 该热储中母地热流体的Cl-质量浓度为265 mg/L, 温度为336 ℃.在热海热田, 母地热流体在经历绝热冷却过程后直接形成了泉口温度最高的大滚锅泉, 而其他中性泉均由母地热流体先与浅部地下冷水混合再经历绝热冷却形成.母地热流体的深部热储之上存在多个温度在200 ℃以上的热储, 这些热储的形成受控于热海地区发育的多组方向不同的断裂. 相似文献