Analysis of Water Resources Supply and Demand and Security of Water Resources Development in Irrigation Regions of the Middle Reaches of the Heihe River Basin, Northwest China

Based on the data for meteorology, hydrology, soil, planting, vegetation, and socio-economic development of the irrigation region in the middle reaches of the Heihe River basin, Northwest China, the model of balance of water supply and demand in the region was established, and the security of water resource was assessed, from which the results that the effects of unified management of water resources in the Heihe River basin between Gansu Province and Inner Mongolia on regional hydrology are significant with a decrease in water supply diverted from Heihe River and an increase in groundwater extracted. In addition, it was found that the groundwater level has been steadily decreasing due to over pumping and decrease in recharges. In present year （2003）, the volume of potential groundwater in the irrigation districts is far small because of the groundwater overdraft; even in the particular regions, there is no availability of groundwater resources for use. By 2003, water supply is not sufficient to meet the water demand in the different irrigation districts, the sustainable development and utilization of water resources are not secured, and the water supply crisis occurs in Pingchuan irrigation district. Achieving water security for the sustainable development of society, agriculture, economy, industry, and livelihoods while maintaining or improving the abilities of the management and planning of water resources, determining of the reasonable percentage between water supply and groundwater utilization and water saving in agricultural irrigation are taken into account. If this does not occur, it is feared that the present performance of water development and planning may further aggravate the problem of scarcities of water resources and further damage the fragile ecological system.

THE BALANCE BETWEEN SUPPLY AND DEMAND OF WATER RESOURCES AND THE WATER-SAVING POTENTIAL FOR AGRICULTURE IN THE HEXI CORRIDOR

The Hexi Corridor is an important base of agriculture development inNorthwest China. According to recent statistics, there are 65. 94 x 10~8m^3 of water resourcesavailable in the Hexi Corridor. At present, net consumption in development and utilization is 43. 33x 10~8m^3. Water supply and demand reach a balance on the recent level of production, but loss ofevaporation and evapotranspiration is as much as 25. 69 x 1010~8m^3. So net use efficiency of waterresources is 59% Based on analyzing balance between water and land considering ecologicalenvironment at present, there exists the serious water shortage in the Shiyang River system whereirrigation lands have overloaded. There is a comparative balance between supply and demand of waterresource in the Heihe River system; and the Sule River system has some surplus water to extendirrigation land. Use of agriculture water accounts for 83. 3% and ecological forest and grass for 6.9% . The Hexi Corridor still has a great potential for water saving in agriculture production.Water-saving efficiency of irrigation is about 10% by using such traditional technologies as furrowand border-dike irrigation and small check irrigation, and water-saving with plastic film cover andtechniques of advanced sprinkler and drip/micro irrigation etc. can save more than 60% of irrigatedwater. Incremental irrigation area for water-saving potential in the Hexi Corridor has beenestimated as 56% - 197% to original irrigation area. So the second water sources can be developedfrom water saving agriculture in the Hexi Corridor under Development of the Western Part of China inlarge scale. This potential can be realized step by step through developing the water-savingmeasures, improving the ecological condition of oasis agriculture, and optimizing allocation ofwater resources in three river systems.

Analysis on the situation and countermeasures of water resources supply and demand in the cities of small and medium-sized river basins along southeast coast of China-taking Xiamen City as an example

The small and medium-sized river basins along southeast coast of China hold comparatively abundant water resources.However,the rapid resources urbanization in recent years has produced a series of water problems such as deterioration of river water quality,water shortage and exacerbated floods,which have constrained urban economic development.By applying the principle of triple supply-demand equilibrium,this paper focuses on the estimation of levels of water supply and demand in 2030 at different guarantee probabilities,with a case study of Xiamen city.The results show that water shortage and inefficient utilization are main problems in the city,as the future water supply looks daunting,and a water shortage may hit nearly 2×10^(8)m^(3)in an extraordinarily dry year.Based on current water supply-demand gap and its trend,this paper proposes countermeasures and suggestions for developing and utilizing groundwater resources and improving the utilization rate of water resources,which can supply as a reference for other southeast middle-to-small-sized basin cities in terms of sustainable water resources and water environment protection.

A Simple Discussion on the Supply and Demand of Water Resources in the Western Region of China

We are accustomed to solve the problem of the water scarcity in the western region by the thought of increasing the effective supply of water to meet the needs of Go-west Campaign. After introducing the dynamic equilibrium principle on supply and demand in economy, we find that we should solve the problem of the water scarcity in the western region through reducing total demand to achieve the dynamic equilibrium of supply and demand. Finally water resources in the western region can be enlarged by an accumulated way.

Jordan’s Water Resources: Increased Demand with Unreliable Supply

Jordan is a small county located in the Middle East. Jordan has borders with Saudi Arabia, Syria, Iraq, and Israel (Figure 1). Jordan was established in 1921 and has very limited natural resources. Jordan’s current (2008) population is 6.5 million. The country has a total land area of 750,000 km2, about one third (92,300 km2) of which is dry land while the other two thirds (329,000 km2) are irrigated land. Jordan is considered as a water poor country due to unreliable and shortages in the supply of water sector. This makes it very difficult to meet the required and steadily increasing demand. Impact of climate change adds a layer to the uncertainty on the supply side of Jordan’s water portfolio. This paper addresses the water supply challenges that Jordan faces and what has been accomplished to improve supply and/or reduce demand. Many projects were undertaken or planned by the Jordanian government to increase the water supply and improve its reliability. Completing the proposed projects will result in Jordan meeting its water demand [1]. Otherwise, the Jordanian Government implement some or all the proposed short term solutions as presented in this paper.

Problems for water resources development in typical small karst drainage basins and countermeasures

In karst area water deficit is one of the main factors constraining sustainable economic development. In 1979 the comprehensive karstic observational field station was set up in Houzhai drainage basin located,\ in Puding county of Guizhou Province, which can represent most of the small karst drainage basins on the dividing line of the Guizhou Plateau. Geomorphology, water resources and water chemistry were investigated and observed. Based on comparisons of water supply with water demand and analysis of the main problems in water exploitation and utilization. it is found out that the water deficiency was not directly caused by the scarcity of natural water resources. The true reason is the insufficient capacity of water supply caused by the dismatch of the water and soil water resources which can be dealt with by building more irrigation works. Some solutions such as to build scientific basis for water exploitation and utilization and sustainable economic development in karst drainage basins on dividing line of the Guizhou Plateau.

Water Resources Development and Water Utilization in the Gavkhuni River Basin, Iran

Analysis of water supplies and demand over the past 50 years in the Gavkhuni River Basin（GRB） indicate that despite large investments in water resources development the basin remains just as vulnerable to drought as it always has been. During the period of analysis two transbasin diversions and a storage reservoir have been constructed which have more or less doubled the annual supply to water to the basin. But with each water resource development extractive capacity for irrigation, urban and industrial use has increased by the same amount, so that all new water is allocated as soon as it is available. The most recent developments, since 1980, have actually increased vulnerability to drought because extractive capacity is greater than average flow into the basin. Whenever demand exceeds supply all water is extracted from the basin and the tail end dries up. During the past 50 years flows into the salt pan at the downstream end of the basin have been negligible for more than half the time. Prospects for the future are bleak because once the current phase of water resources development is completed no further water supplies are likely, but demand continues to rise at a steady rate. Ultimately agriculture will have to concede water to urban, industrial and environmental demands.

Modeling demand/supply of water resources in the arid region of northwestern China during the late 1980s to 2010

Water demand increases continuously with an increasing population and economic development. As a result, the difference between water supply and demand becomes a sig- nificant issue, especially in arid regions. To figure out the utilization of water resources in the arid region of northwestern China （ARNWC）, and also to provide methodologies to predict the water use in future, three models were established in this study to calculate agricultural irri- gation, industrial and domestic water use in the ARNWC from the late 1980s to 2010. Based on river discharges in the region, the supply and demand of water resources at the river basin level were analyzed. The results indicated that agricultural irrigation demand occupies more than 90% of the total water use in the ARNWC. Total water demand increased from 31.97 km3 in the late 1980s to 48.19 km3 in 2010. Most river basins in this arid region were under me- dium and high water stress. Severe-risk river basins, such as the Shiyang river basin and the eastern part of the northern piedmont of the Tianshan Mountains, were found in this region. It was revealed that the water supply became critical from April to May, which was the season of the lowest water supply as determined by comparing monthly water consumption.

Optimization research on supply and demand system for water resources in the Chang-Zhu-Tan urban agglomeration

Using system analysis theory and methods, a dynamic model of a water resource supply and demand system was built to simulate trends in the supply and demand of water in the Changsha-Zhuzhou-Xiangtan （Chang-Zhu-Tan） urban agglomeration for the period 2012 to 2030. Four scenarios were examined; namely, a traditional development model, an economic development model, a water-saving model, and a coordinated development model. （i） The problem of balancing water resource supply and demand is becoming increasingly conspicuous with a growing population and a rapidly developing economy. （ii） By 2030, water demand is set to reach a total of 105.1 × 10^8 m^3, with a water supply of 5.4 × 10^8 m^3. A coordinated development model for water resource supply could meet the growing demands of socio-economic development, and generate huge comprehensive benefits. This will be the best solution for the development and utilization of a water resource supply and demand system in the Chang-Zhu-Tan urban agglomeration. （iii） We should accelerate the construction of water conservation projects, strengthen the management of water conservation, optimize economic structures, enhance our awareness of the importance of protecting water resources, hasten the recycling of waste water and environmental improvement, and promote utilization efficiency, and support the capabilities of water resources to meet our expectations.

供需平衡视角下昆仑山北坡县域单元地表水资源开发利用潜力初探

定量分析地表水资源开发利用潜力有助于明晰区域水资源禀赋,对区域未来水资源科学规划和可持续开发利用具有重要的指导意义。通过供需水量平衡,从地表径流量、生态需水量、地表水可利用量角度,初步探讨了昆仑山北坡县域单元的地表水资源开发利用潜力,以期为昆仑山北坡科学规划和兵团南进布局提供水资源保障依据。结果表明:(1)昆仑山北坡河流径流2000年后呈显著增加趋势,主要河流2001—2010年年均径流量较2000年以前平均增加了23.36%,2011—2020年较2000年以前平均增加了42.89%,其中车尔臣河增幅最大,和田河增幅最小。(2)车尔臣河流域、克里雅河流域和和田河流域的生态基流量分别为4.67×10^(8)m^(3)、5.38×10^(8)m^(3)和20.26×10^(8)m^(3),天然植被生态需水量分别为4.34×10^(8)m^(3)、4.00×10^(8)m^(3)和2.62×10^(8)m^(3)。(3)昆仑山北坡各县域单元现状地表水已用水量范围为0.1×10^(8)~8.73×10^(8)m^(3),地表水资源潜力范围为-0.07×10^(8)~3.17×10^(8)m^(3),空间差异非常显著,其中水资源潜力大于2.00×10^(8)m^(3)的有墨玉县、铁门关市38团、策勒县、且末县、和田县、民丰县和洛浦县。现状区域的地表水资源调蓄能力不足,水资源利用上限偏低,虽有潜力但有水难用,未来昆仑山北坡各县域单元需制定修编更为适宜的地表水资源规划并加强基础水利工程建设,提升地表水资源利用效率,为区域高质量发展提供水资源支撑保障。

中国水-能-粮耦合系统协同安全发展战略研究

水是水-能-粮(WEF)耦合系统的核心要素,为保障国家粮食和能源安全,必须加强水资源管理,坚持水资源、能源和粮食协同安全发展。在系统总结国内外WEF耦合系统纽带关系研究进展、科学认识WEF基本内涵的基础上,分析了我国各省份水资源、能源、粮食开发利用过程中存在的问题,揭示当前WEF耦合系统发展面临的能源需求持续增长与能源安全结构性矛盾日益凸显、不稳定因素加剧粮食安全风险、资源不匹配带来水资源约束趋紧、高质量发展对水-能-粮-生提出更高要求四大挑战,围绕区域特点和高质量发展目标,针对性提出了区域可持续发展模式与策略。研究建议,在西北资源富集地区,通过“四水四定”、水权交易及调水工程缓解水资源短缺;在京津冀地下水超采区,优化粮食安全布局,强化水与能源协同调控;在东北粮食增产区,拓展粮食生产空间,保护水资源合理开发利用;在南方水资源丰沛区,深化农业供给侧结构性改革,统筹“水风光储”一体化开发,以期为实现绿色低碳的可持续发展路径提供科学支撑与决策参考。

三水河流域农业生产空间水资源时空匹配性分析与调控研究

水资源短缺是长期制约农业经济发展的关键因素之一.针对以雨养农业为主的三水河流域农业用水需求大、水资源短缺以及用水效率低的突出问题,该研究采用水平衡理论和Penman-Monteith法,在年度、月度与作物层面上分别得到2020年三水河各子流域单元农业生产空间的供、需水量,分析供需匹配的时空特征,并判断供需矛盾的等级与类型.结果表明,三水河流域农业生产空间水资源供需匹配存在空间和时间错位性,水资源匹配性北高南低;年度农业用水整体处于“水平衡-临界匮缺”的匹配性等级,农业主产小流域水匮缺程度相对严重;月度农业生产空间水资源匹配性时空差异显著,盈余型、匮缺型和盈匮相持型小流域并存;作物用水匹配性整体表现为苹果>玉米>小麦,苹果用水的匹配关系接近于平衡,为流域用水方面的优势作物.据此,研究提出农业生产空间调控建议,为提高三水河流域农业生产水资源利用效率和优化农业空间布局提供参考.

基于生态需水的黄河中游水平衡分析--以沁河流域为例

为推动黄河流域生态保护及高质量发展,解决地表水资源供需矛盾,亟需开展水平衡分析,建立水平衡模型,为水资源合理分配提供参考依据。作为黄河的重要支流,沁河流域位于黄河中游末端,由于近年来上游调水政策的施行以及流域内生活、生产用水的增加,用水矛盾突出,出现了河道断流、入黄水量偏枯等问题。为保障河流生态环境健康,优化引沁入汾跨流域提水工程实施后的流域水资源供需平衡,以2021年为现状年,在“自然-人工”二元水循环研究理论的指导下,运用水平衡分析理论与方法,以河道内生态需水为保障基础,对沁河流域水资源需求、供水能力与供需平衡进行了分析与讨论。结果表明:(1)沁河流域水资源供给和需求在空间分布上具有分异性,上游山西省境内各河段河道内均能够保障适宜的生态需水量,下游河南省境内,仅可满足最小生态需水量;(2)沁河流域可供给水资源总量为10.04×10^(8)m^(3),河道外生产、生活及生态用水总量为8.89×10^(8)m^(3),剩余河道内水量仅为1.15×10^(8)m^(3),仅可满足河流最小生态需水;(3)推算至2030年,流域内工业生产及生活取用地表水量将达到6.98×10^(8)m^(3),河道外用水总量将达到9.81×10^(8)m^(3),剩余水量无法满足最小生态需水。建议采用降低工业用水量、提高农田灌溉用水利用率、推广使用高效节水技术,进一步增强水资源的有效利用,改善流域生态环境。研究结果可为合理规划沁河流域水资源调度提供参考,也可为黄河中游水平衡分析提供范例。

河北省邢台市百泉泉域水资源供需平衡分析

为保证邢台市百泉泉域持续复涌,通过分析研究区域现状供、需水量情况,并预测该区域总需水量、地表水供水量、地下水供水量、非常规水和外调水量相关指标,定量分析水资源供需平衡。结果得出,上游水库的供水量可进一步置换泉域内生活、工业、农业用水及补充下游河道生态用水,各县(市、区)地下水开采量仍较高,而地表水实际利用量相对与地表水可供水量仍较低。建议该区域减少地下水开采量,科学合理分配利用地表水。

沈阳现代化都市圈水供给服务供需平衡研究

以沈阳现代化都市圈为研究区,从地级市尺度上综合自然水文过程和居民生产、生活消费需求,揭示区域水供给服务供需平衡关系,为区域水资源优化管理提供依据。基于GIS平台,采用2000、2010和2020年土地利用数据,耦合InVest模型产水量模块、水需求服务模型、水资源安全指数等多种方法,以空间可视化的方式模拟研究水供给服务格局。研究结果表明:2000-2020年沈阳现代化都市圈水供给量和水需求量均呈现先增多后减少的趋势,供需平衡状况差距较大;2000年沈阳市、鞍山市、辽阳市、铁岭市、阜新市的水资源安全指数以及2010年、2020年沈阳市、辽阳市水资源安全指数均低于0.5;研究区水供给服务的供给与需求在空间分布上呈现显著的不匹配特征,区域东部铁岭市、抚顺市、本溪市为主要供给区,中部沈阳市、辽阳市需大于供,水资源供需矛盾突出。研究框架思路与研究结果能够为都市圈尺度水资源供需矛盾的协调提供一定的决策依据。

国家级水利风景区空间格局及其资源供需评价

水利风景区是以水域岸线或水利工程为依托的专题性景区,对建设幸福河湖、实现全流域生态保护和促进水利高质量发展具有重要作用。揭示了国家级水利风景区在全国尺度下的空间格局,借助可达机会累计算法对水利风景资源的地域供需进行评价。结果表明:(1)景区分布在全国尺度上表现出以人口格局为主导的空间特征,在胡焕庸线以东密集成簇、以西稀疏散布;(2)景区与城市的连接网络呈现多层级性;以省为单元的组团化结网特征明显,省际间的连通性不足;(3)水利风景资源供给与居民需求整体上呈现出空间不匹配特性,资源供需比局部出现西北高,京津冀、华南及西南低的空间差异。研究结果可为水利风景资源的调控与配置提供依据。

基于水资源刚性约束的城市节水潜力分析

为满足水资源刚性约束制度的要求,有效保障城市农业、生活及生产用水安全,以江苏省宿迁市为例开展不同规划年各来水条件情景下的节水潜力分析。用水总量控制管理是落实水资源刚性约束的重要标准,在节水潜力计算过程中,基于节水目标与强度设定了“基本方案”与“节水方案”,以区域用水总量控制指标为约束,构建了基于目标控制的节水潜力模型,从农业、第二第三产业、生活3个模块分析规划年宿迁市可节水量。结果表明:采用“节水方案”后,宿迁市基本能够满足水资源供需平衡,在P=95%的来水频率下,仅沭阳县处于轻度缺水状态;在P=50%来水频率下,发展至2025年及2030年,宿迁市全市节水潜力分别可达7.5069亿m^(3)和6.9293亿m^(3);在宿迁市两区三县中,沭阳县可节水量最大,未来应合理规划,充分挖掘地区节水潜力。研究成果可为区域节水潜力发展提供参考。

Water Resource Allocation under Consideration of the National NIY Plan in Harbin, China

Water resource allocation （WRA） is a useful but complicated topic in water resource management. With the targets set out in the Plan of Newly Increasing Yield （NIY） of 10×1011 Jin （1 kg=2 Jin） from 2009 to 2020, the immediate question for the Songhua River Region （SHRR） is whether water is sufficient to support the required yield increase. Very few studies have considered to what degree this plan influences the solution of WRA and how to adapt. This paper used a multi-objective programming model for WRA across the Harbin region located in the SHRR in 2020 and 2030 （p=75%）. The Harbin region can be classified into four types of sub-regions according to WRA： Type I is Harbin city zone. With rapid urbanization, Harbin city zone has the highest risk of agricultural water shortage. Considering the severe situation, there is little space for Harbin city zone to reach the NIY goal. Type II is sub-regions including Wuchang, Shangzhi and Binxian. There are some agricultural water shortage risks in this type region. Because the water shortage is relatively small, it is possible to increase agricultural production through strengthening agricultural water-saving countermeasures and constructing water conservation facilities. Type III is sub-regions including Acheng, Hulan, Mulan and Fangzheng. In this type region, there may be a water shortage if the rate of urbanization accelerates. According to local conditions, it is needed to enhance water-saving countermeasures to increase agricultural production to a certain degree. Type IV is sub-regions including Shuangcheng, Bayan, Yilan, Yanshou and Tonghe. There are good water conditions for the extensive development of agriculture. Nevertheless, in order to ensure an increase in agricultural production, it is necessary to enhance the way in which water is utilized and consider soil resources. These results will help decision makers make a scientific NIY plan for the Harbin region for sustainable utilization of regional water resources and an increase in agricultural production.

引黄灌区水资源承载力多目标决策模型

开展灌区水资源承载力多目标决策研究,探究灌区水资源、社会经济以及生态环境三者之间的互动关系,对可持续性灌区建设具有重要意义。以赵口引黄灌区二期工程为研究对象,以灌区经济效益最大、缺水率最小、承载人口总量最多、污染物排放量最小以及粮食产量最大为目标,综合考虑灌区供需水能力、灌溉面积、污染物排放等多维临界约束,构建了赵口引黄灌区二期工程水资源承载力多目标决策模型,运用第3代非支配排序遗传算法(NSGA-Ⅲ)进行求解,获得Pareto最优解集,并依据不同的目标偏好和熵权法从中选取多套决策方案。研究结果表明:文中经济效益最大、社会效益最大、生态效益最大、人口总量最大以及粮食产量最大5个目标相互制约,Pareto非劣解侧重于追求其中一方效益最优的同时,必然会引起其他目标值(至少一个)变劣。因此,文中得到的多种决策方案可为灌区未来水资源承载力的提升提供科学理论指导。

广西西江流域及主要支流水量分配方案分析

以水利部分配给广西的流域水量控制指标及各市用水总量控制指标为依据,统筹考虑调入与调出、河道内与河道外用水、用水与消耗等关系,开展广西西江及其主要干支流水资源供需平衡和水资源配置分析,合理确定本流域地表水资源的可分配水量。并综合考虑流域内区域间用水关系,依据水资源配置成果,按照水量分配的原则,合理确定广西西江流域及主要支流供各市河道外利用的地表水用水量份额。