• 한국농공학회지
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• 제19권1호
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• pp.4296-4311
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• 1977

This study was conducted to derive an Instantaneous Unit Hydrograph for the accurate and reliable unitgraph which can be used to the estimation and control of flood for the development of agricultural water resources and rational design of hydraulic structures. Eight small watersheds were selected as studying basins from Han, Geum, Nakdong, Yeongsan and Inchon River systems which may be considered as a main river systems in Korea. The area of small watersheds are within the range of 85 to 470$\textrm{km}^2$. It is to derive an accurate Instantaneous Unit Hydrograph under the condition of having a short duration of heavy rain and uniform rainfall intensity with the basic and reliable data of rainfall records, pluviographs, records of river stages and of the main river systems mentioned above. Investigation was carried out for the relations between measurable unitgraph and watershed characteristics such as watershed area, A, river length L, and centroid distance of the watershed area, Lca. Especially, this study laid emphasis on the derivation and application of Instantaneous Unit Hydrograph (IUH) by applying Nash's conceptual model and by using an electronic computer. I U H by Nash's conceptual model and I U H by flood routing which can be applied to the ungaged small watersheds were derived and compared with each other to the observed unitgraph. 1 U H for each small watersheds can be solved by using an electronic computer. The results summarized for these studies are as follows; 1. Distribution of uniform rainfall intensity appears in the analysis for the temporal rainfall pattern of selected heavy rainfall event. 2. Mean value of recession constants, Kl, is 0.931 in all watersheds observed. 3. Time to peak discharge, Tp, occurs at the position of 0.02 Tb, base length of hlrdrograph with an indication of lower value than that in larger watersheds. 4. Peak discharge, Qp, in relation to the watershed area, A, and effective rainfall, R, is found to be {{{{ { Q}_{ p} = { 0.895} over { { A}^{0.145 } } }}}} AR having high significance of correlation coefficient, 0.927, between peak discharge, Qp, and effective rainfall, R. Design chart for the peak discharge (refer to Fig. 15) with watershed area and effective rainfall was established by the author. 5. The mean slopes of main streams within the range of 1.46 meters per kilometer to 13.6 meter per kilometer. These indicate higher slopes in the small watersheds than those in larger watersheds. Lengths of main streams are within the range of 9.4 kilometer to 41.75 kilometer, which can be regarded as a short distance. It is remarkable thing that the time of flood concentration was more rapid in the small watersheds than that in the other larger watersheds. 6. Length of main stream, L, in relation to the watershed area, A, is found to be L=2.044A0.48 having a high significance of correlation coefficient, 0.968. 7. Watershed lag, Lg, in hrs in relation to the watershed area, A, and length of main stream, L, was derived as Lg=3.228 A0.904 L-1.293 with a high significance. On the other hand, It was found that watershed lag, Lg, could also be expressed as {{{{Lg=0.247 { ( { LLca} over { SQRT { S} } )}^{ 0.604} }}}} in connection with the product of main stream length and the centroid length of the basin of the watershed area, LLca which could be expressed as a measure of the shape and the size of the watershed with the slopes except watershed area, A. But the latter showed a lower correlation than that of the former in the significance test. Therefore, it can be concluded that watershed lag, Lg, is more closely related with the such watersheds characteristics as watershed area and length of main stream in the small watersheds. Empirical formula for the peak discharge per unit area, qp, ㎥/sec/$\textrm{km}^2$, was derived as qp=10-0.389-0.0424Lg with a high significance, r=0.91. This indicates that the peak discharge per unit area of the unitgraph is in inverse proportion to the watershed lag time. 8. The base length of the unitgraph, Tb, in connection with the watershed lag, Lg, was extra.essed as {{{{ { T}_{ b} =1.14+0.564( { Lg} over {24 } )}}}} which has defined with a high significance. 9. For the derivation of IUH by applying linear conceptual model, the storage constant, K, with the length of main stream, L, and slopes, S, was adopted as {{{{K=0.1197( {L } over { SQRT {S } } )}}}} with a highly significant correlation coefficient, 0.90. Gamma function argument, N, derived with such watershed characteristics as watershed area, A, river length, L, centroid distance of the basin of the watershed area, Lca, and slopes, S, was found to be N=49.2 A1.481L-2.202 Lca-1.297 S-0.112 with a high significance having the F value, 4.83, through analysis of variance. 10. According to the linear conceptual model, Formular established in relation to the time distribution, Peak discharge and time to peak discharge for instantaneous Unit Hydrograph when unit effective rainfall of unitgraph and dimension of watershed area are applied as 10mm, and $\textrm{km}^2$ respectively are as follows; Time distribution of IUH {{{{u(0, t)= { 2.78A} over {K GAMMA (N) } { e}^{-t/k } { (t.K)}^{N-1 } }}}} (㎥/sec) Peak discharge of IUH {{{{ {u(0, t) }_{max } = { 2.78A} over {K GAMMA (N) } { e}^{-(N-1) } { (N-1)}^{N-1 } }}}} (㎥/sec) Time to peak discharge of IUH tp=(N-1)K (hrs) 11. Through mathematical analysis in the recession curve of Hydrograph, It was confirmed that empirical formula of Gamma function argument, N, had connection with recession constant, Kl, peak discharge, QP, and time to peak discharge, tp, as {{{{{ K'} over { { t}_{ p} } = { 1} over {N-1 } - { ln { t} over { { t}_{p } } } over {ln { Q} over { { Q}_{p } } } }}}} where {{{{K'= { 1} over { { lnK}_{1 } } }}}} 12. Linking the two, empirical formulars for storage constant, K, and Gamma function argument, N, into closer relations with each other, derivation of unit hydrograph for the ungaged small watersheds can be established by having formulars for the time distribution and peak discharge of IUH as follows. Time distribution of IUH u(0, t)=23.2 A L-1S1/2 F(N, K, t) (㎥/sec) where {{{{F(N, K, t)= { { e}^{-t/k } { (t/K)}^{N-1 } } over { GAMMA (N) } }}}} Peak discharge of IUH) u(0, t)max=23.2 A L-1S1/2 F(N) (㎥/sec) where {{{{F(N)= { { e}^{-(N-1) } { (N-1)}^{N-1 } } over { GAMMA (N) } }}}} 13. The base length of the Time-Area Diagram for the IUH was given by {{{{C=0.778 { ( { LLca} over { SQRT { S} } )}^{0.423 } }}}} with correlation coefficient, 0.85, which has an indication of the relations to the length of main stream, L, centroid distance of the basin of the watershed area, Lca, and slopes, S. 14. Relative errors in the peak discharge of the IUH by using linear conceptual model and IUH by routing showed to be 2.5 and 16.9 percent respectively to the peak of observed unitgraph. Therefore, it confirmed that the accuracy of IUH using linear conceptual model was approaching more closely to the observed unitgraph than that of the flood routing in the small watersheds.

• 한국수자원학회논문집
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• 제37권5호
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• pp.407-424
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• 2004

본 연구는 지형 기후학적 단위유량도(Geomorphoclimatic Unit Hydrograph, GCUH)가 산악지역의 유출량과 돌발홍수 기준우량을 산정하는데 적절한지를 검토한 것으로, 우선 산악지역의 유출량을 산정하는데 적절한 방범인지를 덕천강 유역에 대해 확률강우량으로 지형기후학적 단위유량도의 첨두유량과 기존 보고서의 착률 홍수량 자료를 비교하는 방법과 실측 호우사상을 HEC-HMS(Hydrologic Engineering Center-Hydrologic Modeling System) 모형과 지형기후학적 단위유량도에서 산정된 첨두 유량을 태수지점의 실측자료와 비교함으로써 지형기후학적 단위유량도의 타당성을 검증하려했고 지형기후학적 단위유량도와 NRCS(Natural Resources Conservation Service) 방법을 이용하여 돌발홍수 기준우량을 산정함으로써 산악지역의 돌발홍수 기준우량 산정 방법을 제시했다. 덕천강 유역에 대해 확률강우량으로 첨두 유량을 비교한 경우 표 11과 같이 대체로 30년 빈도를 제외하곤 비율이 1.1을 초과하지 않았고, 실측 호우사상으로 첨두유량을 비교한 경우 표 12와 같이 지형기후학적 단위유량도 결과가 HEC-HMS 모형보다 모두 크게 나타났고 태수 수위표의 실측치와 대체로 유사하게 나타났다. 따라서, 본 연구에서 지형기후학적 단위유량도를 이용한 산악지역의 유출량 산정이 타당함을 확인했고 이를 이용해 덕천강 유역의 돌발홍수 기준우량을 산정한 결과 한계유출량이 95.59 $m^3$/sec일때, 최초 10분 동안에 12.96 mm가 발생하면 위험한 것으로 나타났다.

• 한국수자원학회논문집
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• 제53권5호
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• pp.383-393
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• 2020

본 연구에서는 소양강댐 유역에서의 실측 단일사상 강우-유출 자료를 활용하여 Clark 단위도 방법의 매개변수를 최적화 하였으며, 그 결과를 제시하였다. 일반적으로 국내에서는 유역특성인자 최적화 분석시 미육군공병단의 HEC-1, HEC-HMS 등의 모형을 사용하고 있다. 그러나 해당 모형의 경우 유출수문곡선의 형상, 크기 등의 재현에만 초점이 맞춰져 있으며, 산정된 매개변수들의 평균을 사용하고 있어 실제 강우-유출 관계를 묘사하는데 어려움이 존재하고 있다. 이러한 점에서 본 연구에서는 기존 Clark 합성단위도법과 계층적 Bayesian 기법을 결합하여 수집된 강우-유출 자료를 동시에 활용하여 매개변수를 산정할 수 있는 모형을 개발하였다. 본 연구에서 개발된 모형을 적용한 결과 개별 단일사상 기반의 최적화 기법에 비해 다중 강우-유출 자료를 Pooling하여 매개변수를 산정하는 계층적 Bayesian 모형에서 BIC 결과 및 다수의 통계적 지표를 통해 모형의 우수성을 확인할 수 있었다. 더불어 홍수량에 따른 유역특성인자 매개변수 반응에 대한 관계규명을 기반으로 향후 댐 설계 또는 PMF 산정시 본 연구의 결과가 활용이 가능할 것으로 판단된다.

• 대한토목학회논문집
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• 제35권6호
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• pp.1269-1276
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• 2015

수문모형 기반의 강우강도-지속시간-홍수량(IDQ) 곡선을 이용하여 홍수예보에 활용하는 기법을 소개하고 그 성능을 평가하였다. 이를 위하여 계측된 유역의 자료를 이용하여 집중형 모형의 검보정을 실시하고 하천의 특보 홍수량에 준하는 등가강우량을 산정하였다. 특보홍수량과 선행함수상태별 IDQ 곡선을 산정되면 발생 가능한 여러 시나리오에 대비할 수 있다. 시범대상유역은 강원도에 위치한 원주천 유역 ($94.4km^2$)이며 주의보 수위(계획홍수량의 50%)와 경보 수위(계획홍수량의 70%)에 해당하는 IDQ 곡선이 산정되었다. 과거 10년간의 자료로부터 선행함수 조건별 IDQ곡선의 홍수예보능력을 평가한 결과, 탐지확률은 0.704, 경보실패율은 0.136, 임계성공지수는 0.633으로 나타났으며, 단일 조건의 IDQ 곡선을 적용한 홍수예보능력에 비해 더 나은 평가지수를 얻을 수 있었다.

• 한국수자원학회논문집
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• 제37권9호
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• pp.707-718
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• 2004

최근 빈번한 기상이변에 따라 발생되는 자연재해에 대한 방재대책의 중요함이 절실히 요청되는 시점에서 수공구조물들의 설계빈도를 상향조정하는 등의 대책이 마련되고 있는 실정을 고려하여 유역의 수문학적 안정성을 확보하기 위한 최적방안을 마련하는데 필요한 강우의 임계지속시간 결정에 대한 연구를 수행하였다. 특히 2002년 여름 강릉지역에 발생한 태풍 "루사"로 인한 집중호우는 기존 PMP 규모를 초과하는 사상 초유의 24시간 최대 강수량(880mm)을 기록하여 댐설계기준에 대한 재고가 불가피 하게 되었다. 홍수제어를 위한 수공구조물은 그 특성상 계획홍수량 결정에 최대치 개념이 도입되어야 하므로, 설계강우의 지속기간을 결정할 경우 강우로 인한 최대유출과 홍수총량이 최대가 되는 임계지속시간을 이용하여 검토하는 것이 필요하다 본 연구에서는 합성단위도(Clark방법, Nakayasu방법, SCS방법)등 각 수문요소에 따른 임계지속시간의 변동양상을 파악한 결과 24시간 강우지속시간시 총유출량 보다 임계지속시간개념으로 산정한 유출량이 크게 산출되었으며, PMP시 적용된 시간분포모형 (Huff 4분위법, IDF곡선 분포법, Mononobe방법)별 적합성을 기왕최대 실측치와 비교ㆍ평가함으로써 수문설계시 활용 할 수 있는 자료를 제시하고자 하였다.

• 한국환경과학회지
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• 제26권12호
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• pp.1321-1331
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• 2017

This study reviewed the applicability of the existing flood discharge calculation method on Jeju Island Han Stream and compared this method with observation results by improving the mediating variables for the Han Stream. The results were as follows. First, when the rain-discharge status of the Han Stream was analyzed using the flood discharge calculation method of the existing design (2012), the result was smaller than the observed flood discharge and the flood hydrograph differed. The result of the flood discharge calculation corrected for the curve number based on the terrain gradient showed an improvement of 1.47 - 6.47% from the existing flood discharge, and flood discharge was improved by 4.39 - 16.67% after applying the new reached time. In addition, the sub-basin was set separately to calculate the flood discharge, which yielded an improvement of 9.92 - 32.96% from the existing method. In particular, the steepness and rainfall-discharge characteristics of Han Stream were considered in the reaching time, and the sub-basin was separated to calculate the flood discharge, which resulted in an error rate of -8.77 to 8.71%, showing a large improvement of 7.31 - 28.79% from the existing method. The flood hydrograph also showed a similar tendency.

• 물과 미래
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• 제10권1호
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• pp.53-70
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• 1977

The analysis performed here is aimed to increase the familiarity of hydrologic process especially for the small basins which are densely gaged. Kyung An and Mu Shim river basins are selected as a representative basin according to the criteria which UNESCO has established back in 1964 and being operated under the auspice of Ministry of Construction. The data exerted from these basins is utilized for the determination of characteristics of procipitation and runoff phenomena for the small basin, which is considered as a typical Korean samall watershed. The study found that the areal distribution of preciptation did not show any significant deviation from the point rainfall. Since the area studied is less than 20 km#, the pointrainfall may be safely utilized as a representative value for the area. Also the effect of elevation on the precipitation has a minor significance in the small area where the elevation difference is less than 200m. The methodology developed by Soil Conservation Service for determination of runoff value from precipitation is applied to find the suitability of the method to Korean river basin. The soil cover complex number or runoff curve number was determined by comsidering the type of soil, soil cover, land use and other factors such as antecedent moisture content. The average values of CN for Kyung An and Mushim river basins were found to be 63.9 and 63.1 respectively under AMC II, however, values obtained from soil cover complex were less than those from total precipitation and effective precipitation about 10-30%. It may be worth to note that an attention has to be paid in application of SCS method to Korean river basin by adjusting 10-30% increase to the value obtained from soil cover complex. Finally, the design flood hydrograph was consturcted by employing unit hydrograph technique to the dimensionless mass curve. Also a stepwise multiple regression was performed to find the relationship between runoff and API, evapotranspiration rate, 5 days antecedentprecipitation and daily temperature.

• 한국농공학회논문집
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• 제62권1호
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• pp.17-27
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• 2020

The objective of this study was to assess the flood probability based on temporal distribution of forecasted-rainfall in Cheongmicheon watershed. In this study, 6-hr rainfalls were disaggregated into hourly rainfall using the Multiplicative Random Cascade (MRC) model, which is a stochastic rainfall time disaggregation model and it was repeated 100 times to make 100 rainfalls for each storm event. The watershed runoff was estimated using the Clark unit hydrograph method with disaggregated rainfall and watershed characteristics. Using the peak discharges of the simulated hydrographs, the probability distribution was determined and parameters were estimated. Using the parameters, the probability density function is shown and the flood probability is calculated by comparing with the design flood of Cheongmicheon watershed. The flood probability results differed for various values of rainfall and rainfall duration. In addition, the flood probability calculated in this study was compared with the actual flood damage in Cheongmicheon watershed (R² = 0.7). Further, this study results could be used for flood forecasting.

• 한국수자원학회논문집
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• 제35권2호
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• pp.173-186
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• 2002

설계홍수량 산정에는 강우-유출 모형이 주로 사용되고 있으며 이 모형의 가장 중요한 인자는 확률강우량과 단위도이다. 따라서, 확률강우량을 합리적이고 정확하게 산정하는 것은 가장 중요한 과정이다. 국내의 경우, 확률강우량은 유역면적이 일정 기준을 초과할 경우에는 면적확률강우량을 사용하여야 하나 지점평균확률강우량을 주로 사용하고 있다. 이에 따라 확률강우량은 상당히 높게 사용하는 반면 단위도는 상대적으로 낮게 사용하고 있어서 개선 이 필요한 실정이다. 본 연구에서는 기존에 일반적으로 사용되고 있는 1일, 2일 강우량을 24시간, 48시간 강우량으로 변환하기 위한 계수를 제시하였으며, 유역의 동시간 강우자료를 이용하여 임의시간 면적강우량 자료계열을 작성하였다. 또한 자료계열의 빈도해석을 통하여 기존의 지점평균확률강우량과 면적확률강우량을 산출한 후 면적에 따른 지점평균확률강우량의 면적확률강우량으로의 감소율인 면적감소계수론 산정하였다. 본 연구에서 제시하는 면적감소계수는 지점평균강우량에서 면적확률강우량을 손쉽게 환산할 수 있는 방안이 된다.

• 대한원격탐사학회지
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• 제21권4호
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• pp.317-327
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• 2005

홍수는 자연재해 중 가장 일반적이며 빈번하게 발생한다. 일반적으로 홍수는 수일간에 걸친 강우에 의하여 발생하지만 집중호우에 의한 돌발홍수는 단 시간에 발생하는 특징이 있다. 본 논문은 지리정보시스템으로 지형자료를 취득한 후 지형기후학적 순간단위유량도로 산악에서 돌발홍수예측을 위한 지리정보시스템의 적용에 관한 연구이다. 본 연구에서의 돌발홍수 발생 범위는 수심이 0.5m, 0.7m, 1.0m 로 설정하였다. 또한, 지속시간별-강우량별 홍수량 조견표를 작성하여 홍수대피 기준을 제안하였다. 본 연구는 기존의 획일된 경보 발령시스템에 비하여 유역에 적합한 기준을 제시하여 지형정보를 고려한 경보발령시스템에 적용이 가능할 것으로 판단된다.