• 한국농공학회:학술대회논문집
• /
• 한국농공학회 2002년도 학술발표회 발표논문집
• /
• pp.33-36
• /
• 2002

The purpose of this study is to develope a indicator for agricultural water use. Agricultural water is challenged by the increase of water use in the sectors of urbanization and industry and social pressure to use water in sustainable and environmentally sound way. The development of agricultural environment indicators is divided into 13 sectors, among which agricultural water use indicators include amount and intensity of agricultural water use, efficiency of agricultural water use, shortage or surplus of water use, water stress, etc.. Agricultural water use indicators provide basic data for sustainable and environmentally sound agricultural development, and also help policy decision makers to solve water shortage problems through water policy and water management measures by making the most of the total available water resources.

• 한국수자원학회:학술대회논문집
• /
• 한국수자원학회 2019년도 학술발표회
• /
• pp.176-176
• /
• 2019

Thailand had issued a national strategic development master plan with issues related to water resources and water security in the entire water management. Water resources are an important factor of living and development of the country's socio-economy to be stable, prosperous and sustainable. Therefore, water management in both multidimensional and multi-sectoral systems is important and will supports socio-economic and environmental development. The direction of national development in accordance with the national strategic framework for 20 years that requires the country to level up security level in terms of water, energy and food. To response to the proposed goals, there is a subplan to increase water productivity of the entire water system for economical development use by evaluating use value and to create more value added from water use to meet international standard level. This study aims to evaluate the water productivity of Thailand in each basin and all sectors such as agricultural sector, service and industrial sectors by using the water use data from water account analysis and GDP data from NESDB during the past 10 years (1996-2015). The comparison of water productivity with other countries will also be conducted and in addition, the measures to improve water productivity in next 20 years will be explored to response to the National Strategic Master Plan goals. Water productivity is defined as output per unit of water depleted. The simplest way to compare water productivity across different enterprises is in monetary terms. World Bank presents water productivity as an indication of the efficiency by which each country uses its water resources. There are two data sets used for water productivity analyses, i.e., the first is water use data at end users and the second is Gross Domestic Product. The water use at end users are estimated by water account method based on the System of Environmental-Economic Accounting for Water (SEEA-Water) concept of United Nations. The water account shows the analyses of the water balance between the use and supply of each water resource in physical terms. The water supply and use linkage in the water account analyses separated into each phases, i.e., water sources, water managers, water service providers, water user at end user under water regulators of all kinds of water use activities such as household, industrial, agricultural, tourism, hydropower, and ecological conservation uses. The Gross Domestic Product (GDP), a well- known measuring method of the national economic growth is not actually a comprehensive approach to describe all aspects of national economic status, since GDP does not take into account the costs of the negative impacts to natural resources that result from the overexploitation of development projects, however, at present, integrating the environment with the economy of a country to measure its economic growth with GDP is acceptable worldwide. The study results will show the water use at each basin, use types at end users, water productivity in each sector from 1996-2015 compared with other countries, Besides the productivity improvement measures will be explored and proposed for the National Strategic Master Plan.

• 한국수자원학회:학술대회논문집
• /
• 한국수자원학회 2003년도 학술발표회논문집(1)
• /
• pp.62-65
• /
• 2003

Improvement of the efficiency of the agricultural water use is important for the sustainable water management because the agricultural water use occupied above 60% of the total water use in korea. For the analysis of agricultural water use the Yi-dong experimental site was selected. For the monitoring system of the experimental site, four rainfall gauging stations and twenty-six water level gauging stations are established and operated. Analyses of the measured data are processed for the irrigation efficiency of agricultural water on the eight irrigation areas.

• 상하수도학회지
• /
• 제9권2호
• /
• pp.118-126
• /
• 1995

The variation of the urban water demand and the amount of water in the distribution reservoir was studied with time for a day. The city of Kwangju in Korea was selected as a study area. The population of Kwangju in the end of 1993 was more than one million and two hundred thousand peoples. The average of daily water use in 1993 was about three hundred and fifty thousand tons a day. One day was devided into 12 divisions with a 2 hour increment. The water use demand related to the amount of water in the distribution reservoir was observed for the given time interval of a day. The water use index was defind in percentage that indicates the ratio of the amount of water use for a time interval to the amount of water use for a day. The water use index with consideration of the water stored in the reservoir was found to be useful to manage and to operate the water supply systems in real time.

• International Journal of Computer Science & Network Security
• /
• 제21권1호
• /
• pp.201-206
• /
• 2021

The significance of high-quality development and green total factor productivity has attracted widespread attention and research, while few studies on green total factor productivity that considers the use of water resources have been conducted in the context of water shortages and water stress. In this study, the green total factor productivity of water use from 2005 to 2015 in mainland China is evaluated based on the global Malmquist-Luenberger productivity index. Results show that: (1) China's green total factor productivity of water use has been improving since 2005 with an annual global Malmquist-Luenberger productivity index of 1.0104. (2) At the regional level, the eastern zone in mainland China owns the highest green total factor productivity of water use, while that in the intermediate zone ranks last. (3) The green total factor productivity of water use in the southern region (1.0113) significantly higher than that in the northern region (1.0095), and also higher than the national average level in the same period. BPC index has been the most important incluencing factor of green total factor productivity of water use at both national level and regional level since 2011.

• 한국수자원학회논문집
• /
• 제35권4호
• /
• pp.367-374
• /
• 2002

본 연구에서는 지표수와 지하수를 최적 연계 운영하여 장차 다가올 물 부족에 대응할 수 있는 용수 공급 방안을 검토하였다. 최적 지표수, 지하수 연계운영 모형은 용수공급으로 인한 순편익을 최대화하도록 이산미분동적계획법을 사용하여 개발하였다. 시범유역으로 양양 남대천을 선정하여 모형을 적용한 결과, 지표수만 사용하여 용수를 공급하는 것에 비하여 용수공급 신뢰도가 뛰어남을 확인할 수 있었다.

• 농업과학연구
• /
• 제48권3호
• /
• pp.629-642
• /
• 2021

Land-use change has an important role in the hydrologic characteristics of watersheds because it alters various hydrologic components such as interception, infiltration, and evapotranspiration. For example, rapid urbanization in a watershed reduces infiltration rates and increases peak flow which lead to changes in the hydrologic responses. In this study, a physical hydrologic model the soil and water assessment tool (SWAT) was used to assess long-term continuous daily streamflow corresponding to land-use changes that occurred in the Naesungchun river watershed. For a 30-year model simulation, 3 different land-use maps of the 1990s, 2000s, and 2010s were used to identify the impacts of the land-use changes. Using SWAT-CUP (calibration and uncertainty program), an automated parameter calibration tool, 23 parameters were selected, optimized and compared with the daily streamflow data observed at the upstream, midstream and downstream locations of the watershed. The statistical indexes used for the model calibration and validation show that the model performance is improved at the downstream location of the Naesungchun river. The simulated streamflow in the mainstream considering land-use change increases up to -2 - 30 cm compared with the results simulated with the single land-use map. However, the difference was not significant in the tributaries with or without the impact of land-use change.

• 한국토양비료학회지
• /
• 제39권5호
• /
• pp.321-327
• /
• 2006

농업환경지표가 OECD 회원국간의 농업환경 비교와 이를 통한 농업환경 개선과 농업정책 수립에 대한 권고의 수단으로만 작용을 하지만 이것이 향후 통상 무역과 연계될 것은 추측 가능한 사실이다. OECD 농업환경지표를 우리나라에 그대로 적용했을 때 얻어진 지표 값이 우리나라의 농업환경을 사실대로 반영하지 못한다면 우리가 받을 피해는 미래에도 작용할 것이므로 이에 대한 새로운 제안을 통해 우리나라에 적합한 지표를 설정해야 한다. OECD에 의해 제안된 농업용수 사용 강도 지표는 논이나 밭에서 이용되거나 배수 유출되는 물의 특성을 모두 반영한 방법이 아니므로 몬순 기후지대에 속하는 한국에 적당하지 않다. 특히, 여름철 집중호우시기에 년 강우량의 2/3가 내리는 강우 특성은 이를 담수해 저장하는 능력을 가진 농경지의 수자원 보유능과 기타의 농업적 특성을 고려한 계산방법으로 농업용수를 산정해야 한다. 논의 경우 강우가 내리거나 관개가 되었을 때 담수나 침투를 통해 물을 지하로 배수해 지하수를 형성하거나 지표의 배수로나 하천을 통해 강이나 저수지로 상당량의 물을 흘려보내 다시 이용할 수 있도록 해준다. 즉, 농업용수로 계산되어 있는 물의 상당량은 다른 농경지나 생활용수 또는 공업용수나 하천 유지용수로 다시 이용된다. 따라서, 물 사용강도에 이용되는 농업용수는 농경지에서 소모되지 않고 지하수로 흘러 들어가거나 하천으로 유입되는 배출수를 고려하여 계산하는 것이 합리적이다. 이렇게 계산하면 22.9%(2001년)로 OECD 계산방법으로 얻어진 47%보다 24.1%가 낮아진다. 합리적인 농업용수 스트레스 지표를 산출하기 위해서는 각 나라마다 다른 나라와 강을 공유하고 있는지의 여부와 농업을 위한 주 취수원이 무엇인지를 살펴보아 그 나라에 적합한 스트레스 지표를 산출하도록 유도하는 것이 바람직할 것이다. 그러나, 실제 물에 대한 스트레스는 강우량, 수계별 수자원 부존량, 사용가능량, 농업용수 총공급수량, 환경 유지용수를 위한 기준 갈수량 확보 가능성, 농업용수 관리현황 및 저수율 분석, 수계별 농업용수 사용 가능량 및 기상 등이 복잡하게 작용할 것이므로 이 모든 인자들을 포함한 지표를 만들기는 쉬운 일이 아니다. 따라서, 우리나라는 OECD의 스트레스 지표와는 달리 환경 위해성 판단이 필요 없고, 계산이 복잡하지 않으며 우리의 환경에 적합하도록 주 취수원인 농업용 저수지의 저수율로 농업용수 스트레스 지표를 산정 했다. 농업용수 사용 기술적 효율지표는 작물의 재배 생리특성 및 이용특성과 지역마다 차이가 나는 기후의 특성을 반영하지 않은 계산의 결과이다. 그러므로 이러한 특성들을 반영하는 기술적 물 이용효율 지표를 만들기 위해서는 각 지역 또는 나라마다 작물별로 기준이 되는 물 소요량을 산정한 후 그 소요량에 대한 공급된 양의 비율로 WUTE를 결정하는 것이 합리적이다. 지역별, 작물별 특성을 포함해야 하는 농업용수 사용 경제적 효율 지표는 소비된 물을 분모로 삼아 계산에 이용하는 대신에 농업용수 사용 기술적 효율에서 제안한 각 지역 또는 나라마다 작물별로 기준이 되는 물 소요량을 산정한 후 그 소요량에 대한 공급된 양의 비율을 계산식의 분모에 적용하고, 벼의 경우는 생산물의 가격 대신에 지하수가 되는 양과 하천수가 되는 양에 대한 경제적 평가에 더해 논에 많은 양의 물이 관개됨으로서 발생하는 수변 생태계에 의한 환경유지 기능과 온도와 습도가 높은 한국의 기후 특성에서 전체 에너지 밸런스를 유지하는데 기여하는 관개수의 가치에 대한 평가와 더불어 생산물의 가격을 포함하는 것이 합리적일 것이다.

• 물과 미래
• /
• 제27권4호
• /
• pp.135-143
• /
• 1994

본 연구에서는 상수도 급수량의 시간적 변화형태를 조사하고, 수요량의 시간적인 변화량에 통계학적 개념을 이용하여 수요량의 시간적 변화에 관한 확률적 분산모형에 관하여 검정 결정하였다. 연구대상의 지역으로 광주시를 선정하고, 자료로는 2시간 간격으로 측정된 배수지의 수위와 1일 상수도 생산량을 이용하였다. 급수계통의 모형에 통제용적과 연속방정식을 적용하여 2시간별로 변화되는 수요량을 결정하고, 매월 단위로 정리하여 수요수량의 변화를 알 수 있도록 하였다. 2시간별 수요수량은 1일 총 급수량에 대한 백분율로 환산하여 지수화하였으며, 시간별로 변화되는 각각의 급수량은 통계학적으로 추론될 수 있는지 알 수 있도록 분산모형에 관하여 검정을 하였다. 검정결과를 이용하면 시간별 확률 급수량의 산정이나 급수량의 통계학적 해석을 통하여 상수도 시설의 운용에 이용할 수 있는 것으로 판단되었다.

• 설비공학논문집
• /
• 제20권12호
• /
• pp.802-807
• /
• 2008

A Study on Typical Rates of Water-use for School Facilities has been carried out in this work. Water supply system is given much weight in school facilities. Therefore, it set up a basis efficiency using of water sources to calculate typical rates of water use. The results are summarized as follows; 1) On the whole, typical rates of water-use was founded out 15 L/stu. d in pirmary school, 10 L/stu. d in middle school and 30 L/stu. d in high school smaller than the existing it. It was rate of water-use change as season and Max. Rates of water-use was July. 2) I deem that school hours are 5 hour's in primary school, 7 hour's in middle school and 8 hour's in high school. It the concept of 1 hour that is lesson time 40 minutes and resting time 10 minutes in primary school, lesson time 45 minutes and resting time 10 minutes in middle school and lesson time 50 minutes and resting time 10 minutes in high school. 3) It is desired that we calculate the volume of pump and water tank throughout this concept and the size of water tank should be 1.5 times with taking peak load into consideration by this study on typical rate of water-use. 4) The amount of using water increases in gradually and I consider the life cycle of facilities is more than 10 years. As a result, I can forecast that the size will be insufficiency but I deem that if we devise a plan about parallel pumping on water tank space, we can cope with it. Also, it is expected that we can cut back the transport energy by controlling pump volume.