用斜率和曲率湿周法推求河道最小生态需水量的比较

从湿周-流量曲线临界点的两种不同确定准则入手,分析湿周法推求河道内最小生态需水量 (minimum ecological instream flow requirements, 简称MEIFR) 的不确定性。假设河道呈三角形断面和均匀流,得到湿周法的解析解表达式。表达式显示斜率法 (曲线上斜率为1) 和曲率法 (曲线上曲率最大) 二者所得的MEIFR结果迥异。当斜率法取斜率为0.39时,其相应的流量与曲率法结果一致。MEIFR对斜率临界值非常敏感,斜率法中的斜率临界值难以确定,相比而言,曲率法更可靠。这用近似具有三角形断面的南水北调西线一期工程调水区流域的实际数据得到证实。根据我们在该区实地观测和收集的6条河35个河道断面的水深和水宽资料,用解析解估算出各断面的MEIFR。曲率法所估算的MEIFR结果为多年平均流量的2.5%~23.7%,大部分数据落在Tennant法的10%~30%的范围。斜率法为11%~105.7%,普遍偏大,超过这个范围。虽然采用较小的斜率临界点可使斜率法的估算结果变小,然而到底斜率临界点应取何值存在较大的不确定性。这进一步说明,在无法获得一个确定的斜率临界值的情况下,湿周法估算MEIFR宜采用曲率法确定临界点。本文的结果基于理想情况,更普遍的结论有待于对更多种河道断面的探讨。     

辽河流域生态需水估算

从辽河流域存在的环境问题出发,在确定主要生态需水类型的基础上,基于水资源分区,分别估算各水资源分区的不同类型的生态需水,包括枯季河道生态需水、汛期输沙需水、入海需水、地下水恢复需补充的水量、河口湿地生态需水等。针对辽河流域季节性河流的特点,提出了枯水季节最小流量法的枯季河道生态需水计算方法。计算结果表明,辽河流域生态需水总量为130.44×10⁸m³,占地表径流的48.3%,其中浑太河、东辽河2个水资源分区的生态需水量占地表径流的比例在60%以上,辽河干流生态需水量占地表径流的53.5%,其余水资源分区生态需水量占地表径流的比例均在50%以下。研究结果为流域水资源配置及水环境保护与恢复提供科学依据。     

塔里木河下游生态需水估算

量化生态需水是流域水权分配的重要依据。以塔里木河下游大西海子水库至尾闾台特玛湖段为研究区,借助湿周法计算了该段河道内最小生态需水量,并基于2009年和2010年河段地下水分布特征,计算沿线河道两岸各1 km范围地下水恢复至目标埋深(5～4 m)的地下水恢复量,采用潜水蒸发法和面积定额法估算了沿线天然植被生态需水量。结果表明：（1）塔里木河下游大西海子-台特玛湖河道内年最小生态需水量为1.455×108 m3;（2）以5年为恢复期限,确定该河段地下水埋深恢复至5～4 m的年恢复需水量为0.608×108～1.466×108 m3;（3）取潜水蒸发法和面积定额法计算结果均值,确定研究区天然植被生态需水量为1.042×108 m3;（4）综合考虑,塔里木河下游大西海子-台特玛湖年生态需水总量为3.105×108～3.963×108 m3。     

黑河流域莺落峡站河道内生态需水研究

生态需水是当前水问题研究中的一个热点问题, 对于生态环境急剧恶化的内陆干旱区来说, 这一研究尤为紧迫。气候变化及人类活动导致水文变异, 进而改变了当地生态系统的水文及生态平衡状况。文章采用黑河流域莺落峡站1947-2006 年月径流序列资料, 运用差积曲线-秩检验联合法来识别水文过程变异点并分析变异成因, 然后对各月平均流量序列用线性矩法推求GEV分布参数, 求出概率密度最大流量, 将其视为相应月河道内生态流量, 可以得到黑河莺落峡站河道内生态需水情况。结果表明, 基于水文变异情况分析河道内生态需水的计算方法在黑河上游是可行的;水文变异前后, 站点满足生态需水频率会发生显著变化, 因气候原因而导致的径流量变化是很难避免的, 科学合理计算生态需水对干旱区河流生态管理和经济社会可持续发展有重要作用和意义。     

生态环境需水研究现状和展望

生态环境需水是国内外生态水文学研究的热点问题。本文回顾了国内外生态环境需水研究的现状,并对今后生态环境需水研究进行了展望。研究认为:国外对生态需水的研究侧重于河流生态系统,主要是利用所关心的鱼类对河道物理形态、水流状况等变化的响应关系,来确定河流的最小或最佳流量,研究方法主要以水文学法、水力学法和生境模拟法为主。20世纪90年代后,提出了考虑河流生态系统可接受的流量变化,以维持河流生态系统整体功能为目标确定河流生态需水的研究思路。在国内,生态需水研究起步较晚,但发展较快。研究大致经历了二个阶段:1988年至1998年是对生态需水相关概念的认识阶段,1998年之后才真正进入起步性研究阶段。因此,许多理论和方法都有待加强研究。最后,本文提出了以同位素示踪、遥感等技术为支撑,加强生态需水机理和不同时空尺度生态需水转化等问题的研究。     

海河流域平原河道生态环境需水量计算

该文根据海河流域缺乏系统生态数据的特点,提出一种新的生态环境需水量计算方法-高频率流量法。并将其与90％、50％和20％保证率下最枯月平均流量占多年平均流量的百分比进行对比。用该方法计算了海河流域平原河道生态环境需水量,最小需水量为32．25亿m^3,适宜需水量为48．26亿m^3,理想需水量为86．00亿m^3。     

黄淮海平原河道基本环境需水研究

针对我国北方地区水环境中最突出的污染问题,以满足河流最基本的稀释自净功能为目的,提出了一种计算河道基本环境需水量的方法,即月(年)保证率设定法,并以黄淮海平原为例,进行实证分析。结果是黄淮海平原总的河道环境需水最小为2176亿m³,约占多年平均径流量的15%,其中海河流域309亿m³、黄河下游52亿m³、淮河流域片1347亿m³。通过Tennant法验证,说明计算结果可靠。本文的研究不仅丰富了生态(环境)需水的理论内涵,为河道生态(环境)需水的进一步研究打下了良好的基础,同时为研究区水资源规划、水环境保护提供了有力的依据     

新疆孔雀河流域生态基流与天然植被需水量研究

研究和确定流域生态基流及天然植被需水量是为了遏制因河道断流或流量减少而造成的生态环境退化,以确保流域生态系统健康发展。根据孔雀河流域植被类型分布及多年径流状况,将河道分为A、B两部分,A段为孔雀河上游塔什店至第三分水枢纽常年未断流河道;B段为第三分水枢纽以下天然植被主要分布区。基于塔什店水文站近50 a水文数据,结合Tennant法等4种方法对A段河道生态基流进行估算;选择潜水蒸发法、定额法对B段距河道1 km辐射范围内的天然植被需水量进行计算。结果表明:Tennant法估算的年均生态基流为9.13 m³·s^-1,对应基本生态水量为2.88×10⁸ m³·a^-1,满足A段河道2000—2018年多年平均河损,且近10 a(2009—2018年)塔什店实测年均流量均可满足此生态基流标准;B段河道辐射范围内天然植被总面积为4.66×10⁴ hm²,生态需水量为0.95×10⁸ m³·a^-1,以孔雀河生态输水工程为例科学调控水资源,在满足A段基本生态基流的同时兼顾B段天然植被需水量。研究结果对实现孔雀河河道修复和不同水平年下生态供水具有一定的意义。     

宁夏中部干旱带盐池县植被生态需水规律研究

以宁夏中部干旱带盐池县为研究对象,对区域植被生态需水的内涵及类型划分进行了分析,并结合彭曼-蒙特斯模型逐月估算了区域林草植被潜在蒸散量,采用Jensen公式结合实测的区域土壤特征曲线确定了土壤水分修正系数,为植被生态需水量的确定奠定了基础。通过对不同类型林草植被生态需水占比分析,可知当前盐池县草地的生态需水量远高于林地,是盐池县生态需水的主体。通过对植被生态需水与降雨平衡的时间变化规律分析可知,除7、8、9月份以外,盐池县各类林草植被生态需水均处于严重亏缺状态,其中缺水量最为严重的是4月份;从植被类型上分析,可知林地中无论是生态需水亏缺量还是盈余水量均以灌木林地为最,而草地中以天然草地为最。进一步对盐池县各生态分区需水特征进行分析,可知一级生态分区中,风沙区的生态需水比例远大于黄土丘陵区;二级生态分区生态需水比例由大到小依次为花马池镇、王乐井乡、大水坑镇、高沙窝镇、惠安堡镇、冯记沟乡、青山乡、麻黄山乡。一级生态分区中风沙区的生态需水系数及生态需水模数均大于黄土丘陵区;二级各生态分区中生态需水系数及模数由大到小依次为花马池镇、王乐井乡、大水坑镇、惠安堡镇、高沙窝镇、青山乡、冯记沟乡,最小为麻黄山乡。盐池县降雨消耗性生态需水量最小值占蒸发总量的比例为30.51%,适宜值占蒸发总量的比例为72.91%,比例都比较高,其余的的蒸发量属于无效蒸发水量,仍然占有一定的比重,这依然为区域植被建设留有一定的空间,但要通过合理的水资源调控手段进行调配。     

疏勒河中游绿洲天然植被生态需水量估算与预测研究

以疏勒河流域中游绿洲为研究区,借助统计分析法、遥感和GIS技术方法对2013年疏勒河中游绿洲遥感影像土地利用覆盖变化进行解译与分析,得出各种天然植被覆盖状况数据,利用典型的潜水蒸发模型—阿维里扬诺夫公式对研究区内各县区的天然植被生态需水量进行了估算,并对未来天然植被面积和生态需水量进行了预测,为区域生态环境保护与水资源合理分配提供参考。结果表明:疏勒河中游绿洲现状天然植被最小生态需水量为18 768.97×104m3,最大生态需水量为46 643.04×104m3,其中,天然林地生态需水量为1 187.71×104~2 898.72×104m3,天然草地生态需水量为17 581.27×104~43 744.32×104m3,瓜州天然植被生态需水量为9 685.06×104~23 392.09×104m3,玉门天然植被生态需水量6 552.11×104~17 133.45×104m3,敦煌天然植被生态需水量为2 531.80×104~6 117.50×104m3。2020年疏勒河中游绿洲天然植被生态需水量预测为20 655.96×104~66 614.75×104m3,其中,天然林地生态需水量为1 316.57×104~3 855.91×104m3,天然草地生态需水量为19 339.39×104~62 758.84×104m3;2030年疏勒河中游绿洲天然植被生态需水量预测为22 721.55×104~85 584.09×104m3,其中,天然林地生态需水量为1 448.22×104~4 970.08×104m3,天然草地生态需水量为21 273.33×104~80 614.01×104m3。研究结果对促进疏勒河流域生态水权研究、水量分配以及区域生态保护、水资源合理配置与经济社会协调可持续发展具有重要参考意义。指出未来应进一步加强人类活动影响下区域天然植被需水规律研究、不同生态功能区植被生态需水规律以及基于生态保护目标的区域生态需水量及阈值研究。     

用斜率和曲率湿周法推求河道最小生态需水量的比较

1 Introduction With a long term of increasing water demand by industry, agriculture and domestic use along the rivers since the 20th century all over the world, the contradiction between the rational water use and water (ecological) environmental protect…     

Estimating the minimum in-stream flow requirements via wetted perimeter method based on curvature and slope techniques

Under the assumptions of triangular cross section channel and uniform stable flow, an analytical solution of the minimum ecological in-stream flow requirement (MEIFR) is deduced. Based on the analytical solution, the uncertainty of the wetted perimeter method is analyzed by comparing the two techniques for the determination of the critical point on the relationship curve between wetted perimeter, P and discharge, Q. It is clearly shown that the results of MEIFR based on curvature technique (corresponding to the maximum curvature) and slope technique (slope being 1) are significantly different. On the P-Q curve, the slope of the critical point with the maximum curvature is 0.39 and the MEIFR varied prominently with the change of the slope threshold. This indicates that if a certain value of the slope threshold is not available for slope technique, curvature technique may be a better choice. By applying the analytical solution of MEIFR in the losing rivers of the Western Route South-to-North Water Transfer Project in China, the MEIFR value via curvature technique is 2.5%-23.7% of the multi-year average annual discharge, while that for slope technique is 11%-105.7%. General conclusions would rely on the more detailed research for all kinds of cross-sections.     

Stream energy distribution below Eleyele Dam in Southwestern Nigeria

Expressing the rate of energy dissipation either within a basin or in a downstream manner is important in understanding occurrence and association between various morphological variables. This study focuses on the downstream variation in stream power and its relationship with morphological variates along the main channel of River Ona, Ibadan, Nigeria. River Ona stretches for 20.5 km downstream of Eleyele Dam. Twenty‐seven (27) points were sampled along this stretch. The 27 points were averaged into nine (9) reaches. At each cross‐section, channel characteristics were observed and measured. These include: width (W), depth (D), velocity (V), slope (S), Cross‐sectional area (A), discharge (Q), total stream power (TSP), specific stream power (SSP), width‐depth ratio (W/D), hydraulic radius (R) and wetted perimeter (P). This study confirmed that the influence of a dam present upstream of a river channel significantly alters the behaviour of slope and this in essence affects the distribution of energy along the river channel. Slope produces a logarithmic relationship with increasing distance downstream (Y = ‐32.79‐0.70InS, r = 0.70, r2 = 0.49, p < 0.05) while there was no significant relationship between Q and distance downstream.     

描述黄河中下游河道横断面形态的新指标

描述河流横断面的窄深程度,无非是用来衡量它对过流能力和输沙能力的影响大小,及其在河流地貌方面的时空上的调整变化。回顾总结了以往描述横断面形态的常用指标,包括河相系数、宽深比,或湿周与平均水深的比值,指出这几种指标在描述黄河中下游河道时所存在的共同缺点:(1)缺乏物理意义;(2)不能真正代表断面的窄深程度;(3)明显的夸大了宽浅和窄深断面的差别。从表称流量的概念出发,作者认为,应该使用具有明确物理意义的等面积的表称流速来描述断面形态。如果用表称流速来衡量黄河下游河南和山东河道的断面形态的差别,就会发现,断面形态的不同,其对过流能力的影响不过1:2,远不象河相系数和宽深比所描述的达到1:6甚至1:11那样的悬殊程度;黄河下游河道主槽“多来多排”的主要影响因素是表称流速。     

江苏省工业废水排放与经济增长的动态关系

本文研究了1980~2004年江苏省工业废水排放与经济增长的动态关系,结果表明1980年以来江苏省工业废水排放量在波动中平缓增长,排放强度不断下降,主要来源于制造业和能源生产部门,南京市、苏南三市和苏中苏北九市的排放量大致各占排放总量的1/3。采用环境库兹涅茨曲线模型模拟了1980~1996年和1997~2004年工业废水排放量和人均GDP之间的关系,结果显示未来江苏省工业废水排放趋向于在经历较短时间的上升后逐渐下降。采用分解分析方法分析了三种效应在工业废水排放变化中的贡献率,结果表明广义技术效应、规模效应是影响工业废水排放的重要因素,但广义技术效应起到决定性的作用。     

永定河官厅水库下游河道内生态需水量研究

作为北京市母亲河的永定河自上个世纪80年代以来三家店以下一直处于断流,河床裸露、河道两岸土地沙化严重,是北京春季沙尘天气的主要沙源之一,由于地下水超采严重,加之无水补给地下水,使得北京西部地区第四纪地下水已经基本枯竭,永定河的生态系统已经受到严重破坏。要想恢复或治理受损的河道生态环境,作为生态系统中最活跃最重要的水分多少要先算清楚。本文采用湿周法计算了永定河官厅水库下游三个控制断面(官厅水库(坝下)、雁翅、卢沟桥)的河道内生态需水流量,计算结果为:官厅水库(坝下)站的河道内流量为3.7m~3 s~(-1)。(平水年P=50%,1978年),占年平均流量的20.7%,雁翅站的河道内流量为4.1m~3 s~(-1)(平水年P=50%,1981年),占年平均流量的20.1%,卢沟桥站的河道内流量为1.3m~3 s~(-1)(平水年P=50%,1978年),占年平均流量的22.1%。若能按照计算的流量来补充河道水量,即可使永定河恢复其基本的生态功能,按照Tennant法的标准,基本能使当地的河道生态系统处于较为良好的状态。     

Modelling the runoff-sediment yield relationship using a proportional function in hilly areas of the Loess Plateau, North China

Based on data observed at the 12 small watersheds in hilly areas of the Loess Plateau, North China, the relationship between event runoff volume and sediment yield is examined. The results reveal that the runoff-sediment yield relationship at the inter-event timescale is mainly determined by the runoff-sediment concentration relationship at the intra-event timescale. In the study area, the sediment concentration tends to be stable when the flow discharge exceeds a certain critical value. Many factors that are important for determining the characteristics of low-magnitude events, such as flow discharge, particle size of fluvial sediment, and accumulation of loose material on land surfaces prior to a rainstorm, appear to have little importance for high-magnitude events. Consequently, mean sediment concentration tends to be stable for large flood events, suggesting a strong similarity between the two flow-sediment relationships at inter-and intra-event temporal scales. Furthermore, a proportional function is proposed to predict event sediment yield, and the correspondence between the predicted and observed sediment yields is examined. The performance of the model is good for high-magnitude events, especially extreme events. The applicability of the proposed model at the annual timescale is also discussed.     

Estimating extreme flood magnitude in bedrock-influenced channels using representative reach-based channel resistance data

Extreme flood events are considered by many researchers to be very important in controlling the development of semi‐arid bedrock‐influenced river systems. Accurate gauging of such events is often impossible, however, as gauges are drowned and often damaged during the event. A methodology for estimating flood discharge for bedrock‐influenced channels is presented that reconstructs hydrometric characteristics of the peak flow and relates these to the roughness character of the river channel in question. The method is evaluated using peak water‐surface slope data relating to the extreme floods of February 2000 along the Sabie and Letaba rivers, located respectively in the Mpumalanga and Northern Provinces, South Africa. The data, in the form of strandline measurements, were taken at hydraulically relevant points along the long profile of both rivers. The resultant data are utilised together with published high flow channel resistance figures, based on the channel morphology of the Sabie and Letaba rivers, to generate peak flow estimates for a number of locations along both rivers. Comparisons are made between the frictional discharge peak flow estimates, velocity‐area and hydrologic estimates of peak flow. These comparisons indicate that the method can produce discharge estimates with an accuracy of ±10% and ± 35% respectively.     

Surface Moisture Availability and Rock Weathering in Cold Climates

The importance of moisture in determining which rock weathering processes may operate, as well as the rate at which rock weathering occurs, has long been recognised. However, little is known about how often or when moisture is available to the rock surface, or for how long the surface may be wetted. This paper gives some initial results from current research on granite rocks in Antarctica. Recordings of surface moisture, for two aspects and three locations in Victoria Land, show that moisture reaches the rock surface more frequently than might initially have been expected in this dry climate. The number of occasions the surface is wetted, and the quantity of moisture the surface received, varied with aspect and time of year. Rock surfaces could be wet for up to 40% of the time during the summer months. This has important implications for rock weathering where some processes are deemed not to operate, or to operate in very restricted locations, due to the apparent absence of moisture.