• 대한토목학회논문집
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• 제5권2호
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• pp.41-50
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• 1985

본(本) 연구(硏究)에서는 earth dam 파괴로 인한 유출수문곡선(流出水文曲線)의 해석(解析)을 실시(實施)하였다. Earth dam의 파괴에 대하여 이제까지 연구(硏究), 조사(調査) 파괴양상 및 저류방정식등(貯溜方程式等) 바탕으로 DBFW(Dam Break Flood Wave) 모형(模型)을 개발(開發)하였고 개발(開發)된 모형(模型)을 Teton과 Buffalo-Creek 댐에 적용(適用)하여 유출수문곡선(流出水文曲線)을 해석(解析)하였는데 그 결과(結果)는 유출수문곡선(流出水文曲線)의 형상(形狀)이나 첨두유량(尖頭流量) 및 첨두발생시간(尖頭發生時間) 등에 대하여 NWS의 조사결과(調査結果)와 매우 작은 편차(偏差)로 일치(一致)하고 있어 본(本) 모형(模型)의 적용성(適用性)을 입증(立證)하였다. 파괴양상이 유출수문곡선(流出水文曲線)에 미치는 영향은 저수지(貯水池)의 지형학적(地形學的) 특성(特性), 파괴부의 형태(形態), 파괴폭 및 파괴지속시간등이 큰 것으로 나타났으며, 국내 earth dam을 지형학적(地形學的) 특성(特性)에 의하여 4가지 type으로 구분(區分)하고 각각에 대한 수위(水位)-수표면적(水表面積) 관계식(關係式)을 도출(導出)한 후 임의의 댐 높이와 파괴지족시간에 대한 첨두유출량(尖頭流出量) 및 유출수문곡선(流出水文曲線) 구할 수 있는 도표(圖表)를 제시(提示)하였다.

• 한국수자원학회논문집
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• 제56권3호
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• pp.165-171
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• 2023

낙동강 하구둑은 담수와 해수가 만나는 감조하천 환경으로 하구둑에서 방류하는 지표수 유출량과 연안 해저 지하수 유출량에 대한 모니터링이 체계적으로 요구된다. 본 연구에서는 낙동강 하구둑 상류 지역에 위치한 수위자료와 물수지분석을 통하여 변화 저수량과 방류량을 계산하였다. 해저를 통한 육상에서의 지하수 유출도 원격탐사 기반 지형자료와 수문 모델링 자료를 근거로 산출하여 낙동강 하구둑 유출량과 비교 분석하였다. 제안된 방법은 현장 측정 이외의 원격탐사 기반 고도계 자료를 활용하여 수자원 관리에 효율적으로 적용할 수 있을 것으로 판단된다. 담수 지표수 유출량 뿐만 아니라 해저 지하수 유출이 연안에 미치는 영향이 크기 때문에, 낙동강 하구둑 생태계 모니터링에서 담수와 해수의 상호 관계에 대한 연구도 충분히 고려되어야 할 것으로 사료된다.

• 물과 미래
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• 제18권3호
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• pp.265-270
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• 1985

The prediction of a design-flood hydrograph at a particular site on a river may be based on the derivation of discharge or stage hydrograph at an upstream section, togeater with a method to route this hydrograph along the rest of river. On the other hand, flood routing methods provide a useful tool for the analysis of flooding in all but the smaller catchment, and these methods are largely stored into hydrological method and hydraulic method. Although the Muskingum Method as a hydrological method ignores dynamic effects on the flood wave, Muskingum-Cunge Method based on hydraulic method is possible to improve the method so that it gives a good approximation to the solution of the linear convective-diffusion equation. This is made on the basis of the finite diffeience equation for the Muskingum Method. In the study, the outflows predicted by Muskingum-Cunge Method are campared with the observed outflows of the Pyung Chang River.

• 한국지리정보학회지
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• 제9권1호
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• pp.78-88
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• 2006

본 연구에서는 GIS기법을 활용한 산악지역의 돌발홍수 기준우량을 산정하기위해 지형기후학적 순간단위유량도(geomorphoclimatic instantaneous unit hydrograph, GCIUH)와 연계하여 유출해석을 수행하였다. 천동계곡 유역의 평균경사, 면적, 유로특성등 지형자료 구축에 GIS기법을 적용하였으며, 특히 GCIUH의 중요 입력변수인 하천차수 결정시 GIS기법을 활용하여 차수를 선정하였다. 산악지역 유출량 산정의 적합성을 위해 천동계곡 유역($14.58km^2$)에 대한 확률강우량으로 GCIUH의 첨두유량과 기본 보고서의 확률홍수량 자료를 비교하여 적합성을 확인하였다. 적합성이 확인된 GCIUH를 이용하여 천동계곡 유역의 돌발홍수 기준우량을 산정한 결과 한계유출량이 $11.42m^3/sec$일때, 최초 20분간 기준우량이 12.57mm가 발생하면 위험한 것으로 분석되었다.

• 한국농공학회지
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• 제18권1호
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• pp.4079-4086
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• 1976

In many reservoir projects, economic considerations will necessitate a design utilizing surcharge. Determination of the most economical combination of surcharge and spillway capacity for a given spillway crest level will require flood routing studies and economic studies of the dam-reservoir-spillway combinations. Many methods of actual flood routing have been devised, each of them with its advantages and disadvantages. Some of these methods are listed below: (1) Arithmetical trial-and-error method. (2) Modified Puls' method (3) Cheng's graphical method (4) Horton's arithmetical method (5) Ekadahl's arithmetical method (6) Digital computer programming. For the purpose of preliminary design and cost estimating of dams and spillways, it is often required to estimate, for a given design flood and spillway crest level. the approximate values of two among the three characteristics of the spillway spillway length, maximum discharge and surcharge depth at maximum discharge, when one of these quantities is given. As is well known, the outflow hydrograph for an ungated overflow spillway assumes the form of a wave-shaped curve with a minimum point for Q=o At zero time and a maximum point for Q=Qmax at its intersection with the falling leg of the inflow hydrograph (see Fig. 4) The shaded area between the inflow and outflow hydrographs represents at the approximate scale the temporary retention Vt. In line with the remarks, draw by free hand the assumed outflow hydrograph with its maximum point for the given Qmax (see Fig. 4) and by planimetration find Vt. From the reservoir capacity curve (Fig. 3) find Vs for the given spillway crest level and make V=Vs+Vt. From the above curve find surcharge water elevation for V and surcharge depth Hmax over spillway crest. From the discharge formula compute {{{{L= { Q} over { { CH}^{3/2 } } }}}} The methed provides a means for a quick and fairly accurate estimation of spillway capacity.

• Spatial Information Research
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• 제15권2호
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• pp.147-158
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• 2007

강원도 지역은 매년 다양한 재해를 반복적으로 겪고 있으며 이러한 재해는 이 지역의 지속적인 발전에 장애요인이 되고 있다. 특히 2002년 태풍 루사에 의한 집중호우는 막대한 피해와 더불어 우리사회의 많은 교훈을 남겼다. 지역방재계획에는 강우사상에 따른 피난계획이 수립되어 있으나 실제 상황에서는 그 역할을 기대할 수 없었다. 또한 재해복구에 있어서도 원상복구에 그치고 있어 재해에 대한 잠재적 가능성을 그대로 남아 있는 실정이다. 따라서 본 연구에서는 유역의 개발이 수문 유출에 미치는 영향에 대해 종합적으로 고찰하고자 한다.

• 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.

• 한국농공학회지
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• 제38권3호
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• pp.112-126
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• 1996

This study was conducted to develop an optimal runoff bydrograph model by comparison of the peak discharge and time to peak between observed and simulated flows derived by four different models, that is, linear time-invariant, linear time-variant, nonlinear time-invariant and nonlinear time-variant models under the conditions of heavy rainfalls with regionally uniform rainfall intensity in short durations at nine small watersheds. The results obtained through this study can be summarized as follows. 1. Parameters for four models including linear time-invariant, linear time-variant, nonlinear time-invariant and nonlinear time-variant models were calibrated using a trial and error method with rainfall and runoff data for the applied watersheds. Regression analysis among parameters, rainfall and watershed characteristics were established for both linear time-invariant and nonlinear time-invariant models. 2. Correlation coefficients of the simulated peak discharge of calibrated runoff hydrographs by using four models were shown to be a high significant to the peak of observed runoff graphs. Especially, it can be concluded that the simulated peak discharge of a linear time-variant model is approaching more closely to the observed runoff hydrograph in comparison with those of three models in the applied watersheds. 3. Correlation coefficients of the simulated time to peak of calibrated runoff hydrographs by using a linear time-variant model were shown to be a high significant to the time to peak of observed runoff hydrographs than those of the other models. 4. The peak discharge and time to peak of simulated runoff hydrogaphs by using linear time-variant model are verified to be approached more closely to those of observed runoff hydrographs than those of three models in the applied watersheds. 5. It can be generally concluded that the shape of simulated hydrograph based on a linear time-variant model is getting closer to the observed runoff hydrograph than those of three models in the applied watersheds. 6. Simulated hydrographs using the nonlinear time-variant model which is based on more closely to the theoritical background of the natural runoff process are not closer to the observed runoff hydrographs in comparison with those of three models in the applied watersheds. Consequently, it is to be desired that futher study for the nonlinear time-variant model should be continued with verification using rainfall-runoff data of the other watersheds in addition to the review of analyical techniques.

• 한국농공학회지
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• 제37권3_4호
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• pp.34-47
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• 1995

It is experienced fact as a regular annual event that the structure to he designed on unreasonable flood for the agricultural structures including reservoirs have been brought not only loss of lives, but also enormous property damage. For the solution of this problem at issue, this study was conducted to develop an optimal runoff hydrograph model by comparison of the peak flows and time to peak between observed and simulated flows derived by linear time-invariant and linear time-variant models under the condition of having a short duration of heavy rainfall with uniform rainfall intensity at nine small watersheds which are within the range of 55.9 to 140.7 square kilometers in area in Han, Geum, Nagdong and Yeongsan Rivers. The results obtained through this study can be summarized as follows. 1. Storage constants and Gamma function arguments were calculated within the range of 1.2 to 6.42 and of 1.28 to 8.05 respectively by the moment method as the parameters for the analysis of runoff hydrograph based on linear time-invariant model. 2. Parameters for both linear time-invariant and linear time-variant models were calibrated with nine gaged watershed data, using a trial and error method. The resulting parameters including Gamma function argument, N and storage constant, K for linear time-invariant model were related statistically to watershed characteristic variables such as area, slope, length of main stream and the centroid length of the basin. 3. Average relative errors of the simulated peak discharge of calibrated runoff hydrographs by using linear time-variant and linear time-invariant models were shown to be 0.75 and 5.42 percent respectively to the peak of observed runoff hydrographs. Correlation coefficients for the statistical analysis in the same condition were shown to be 0.999 and 0.978 with a high significance respectively. Therefore, it can be concluded that the accuracy of a linear time-variant model is approaching more closely to the observed runoff hydrograph than that of a linear time-invariant model in the applied watersheds. 4. Average relative errors of the time to peak of calibrated runoff hydrographs by using linear time-variant and linear time-invariant models were shown to be 16.44 and 19.89 percent respectively to the time to peak of observed runoff hydrographs. Correlation coefficients in the same condition were also shown to be 0.999 and 0.886 with a high significance respectively. 5. It can be seen that the shape of simulated hydrograph based on a linear time- variant model is getting closer to the observed runoff hydrograph than that of a linear time-invariant model in the applied watersheds. 6. Two different models were verified with different rainfall-runoff events from data for the calibration by relative error and correlation analysis. Consequently, it can be generally concluded that verification results for the peak discharge and time to peak of simulated runoff hydrographs were in good agreement with those of calibrated runoff hydrographs.

• 한국농공학회지
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• 제7권1호
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• pp.861-876
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• 1965

During my stay in the Netherlands, I have studied the following, primarily in relation to the Mokpo Yong-san project which had been studied by the NEDECO for a feasibility report. 1. Unit hydrograph at Naju There are many ways to make unit hydrograph, but I want explain here to make unit hydrograph from the- actual run of curve at Naju. A discharge curve made from one rain storm depends on rainfall intensity per houre After finriing hydrograph every two hours, we will get two-hour unit hydrograph to devide each ordinate of the two-hour hydrograph by the rainfall intensity. I have used one storm from June 24 to June 26, 1963, recording a rainfall intensity of average 9. 4 mm per hour for 12 hours. If several rain gage stations had already been established in the catchment area. above Naju prior to this storm, I could have gathered accurate data on rainfall intensity throughout the catchment area. As it was, I used I the automatic rain gage record of the Mokpo I moteorological station to determine the rainfall lntensity. In order. to develop the unit ~Ydrograph at Naju, I subtracted the basic flow from the total runoff flow. I also tried to keed the difference between the calculated discharge amount and the measured discharge less than 1O~ The discharge period. of an unit graph depends on the length of the catchment area. 2. Determination of sluice dimension Acoording to principles of design presently used in our country, a one-day storm with a frequency of 20 years must be discharged in 8 hours. These design criteria are not adequate, and several dams have washed out in the past years. The design of the spillway and sluice dimensions must be based on the maximun peak discharge flowing into the reservoir to avoid crop and structure damages. The total flow into the reservoir is the summation of flow described by the Mokpo hydrograph, the basic flow from all the catchment areas and the rainfall on the reservoir area. To calculate the amount of water discharged through the sluiceCper half hour), the average head during that interval must be known. This can be calculated from the known water level outside the sluiceCdetermined by the tide) and from an estimated water level inside the reservoir at the end of each time interval. The total amount of water discharged through the sluice can be calculated from this average head, the time interval and the cross-sectional area of' the sluice. From the inflow into the .reservoir and the outflow through the sluice gates I calculated the change in the volume of water stored in the reservoir at half-hour intervals. From the stored volume of water and the known storage capacity of the reservoir, I was able to calculate the water level in the reservoir. The Calculated water level in the reservoir must be the same as the estimated water level. Mean stand tide will be adequate to use for determining the sluice dimension because spring tide is worse case and neap tide is best condition for the I result of the calculatio 3. Tidal computation for determination of the closure curve. During the construction of a dam, whether by building up of a succession of horizontael layers or by building in from both sides, the velocity of the water flowinii through the closing gapwill increase, because of the gradual decrease in the cross sectional area of the gap. 1 calculated the . velocities in the closing gap during flood and ebb for the first mentioned method of construction until the cross-sectional area has been reduced to about 25% of the original area, the change in tidal movement within the reservoir being negligible. Up to that point, the increase of the velocity is more or less hyperbolic. During the closing of the last 25 % of the gap, less water can flow out of the reservoir. This causes a rise of the mean water level of the reservoir. The difference in hydraulic head is then no longer negligible and must be taken into account. When, during the course of construction. the submerged weir become a free weir the critical flow occurs. The critical flow is that point, during either ebb or flood, at which the velocity reaches a maximum. When the dam is raised further. the velocity decreases because of the decrease\ulcorner in the height of the water above the weir. The calculation of the currents and velocities for a stage in the closure of the final gap is done in the following manner; Using an average tide with a neglible daily quantity, I estimated the water level on the pustream side of. the dam (inner water level). I determined the current through the gap for each hour by multiplying the storage area by the increment of the rise in water level. The velocity at a given moment can be determined from the calcalated current in m3/sec, and the cross-sectional area at that moment. At the same time from the difference between inner water level and tidal level (outer water level) the velocity can be calculated with the formula $h= \frac{V^2}{2g}$ and must be equal to the velocity detertnined from the current. If there is a difference in velocity, a new estimate of the inner water level must be made and entire procedure should be repeated. When the higher water level is equal to or more than 2/3 times the difference between the lower water level and the crest of the dam, we speak of a "free weir." The flow over the weir is then dependent upon the higher water level and not on the difference between high and low water levels. When the weir is "submerged", that is, the higher water level is less than 2/3 times the difference between the lower water and the crest of the dam, the difference between the high and low levels being decisive. The free weir normally occurs first during ebb, and is due to. the fact that mean level in the estuary is higher than the mean level of . the tide in building dams with barges the maximum velocity in the closing gap may not be more than 3m/sec. As the maximum velocities are higher than this limit we must use other construction methods in closing the gap. This can be done by dump-cars from each side or by using a cable way.e or by using a cable way.