임도개설(林道開設)에 따른 부유토사량(浮遊土砂量) 변화(變化)(I) -대조유역법(對照流域法)을 중심(中心)으로-

A Study on Change of Suspended Solids by Forest Road Construction(I) -Parallel Watersheds Method-

본(本) 연구(硏究)는 강원대학교(江原大學校) 임과대학(林科大學) 부속연습림(附屬演習林)의 임도개설유역(林道開設流域)을 중심으로 우기(雨期)의 계류수(溪流水)에 함유되어 있는 부유토사량(浮遊土砂量)을 측정하므로써 임도개설(林道開設)에 따른 토사유출(土砂流出) 변화(變化)를 파악하고자 진행하였다. 이를 위해 임도개설유역(林道開設流域)의 강우량(降雨量)과 유출량(流出量), 유출량(流出量)과 부유토사량(浮遊土砂量)의 관계를 규명하였으며, 아울러 임도개설유역(林道開設流域)과 미개설유역(未開設流域)의 강우량(降雨量)에 따른 부유토사량(浮遊土砂量)의 변화에 대하여 비교, 분석하였다. 1. 임도개설유역(林道開設流域)에 있어서 우기(雨期)의 강우량(降雨量)과 유출량(流出量)의 관계는 Table 3 및 Fig. 3와 같이 수문곡선(水文曲線)의 Peakpoint는 강우강도(降雨强度) 및 전강우량(前降雨量) 등에 따라 형성시간(形成時間)과 높이가 상이하였다. 즉 6월(月)12일(日)의 강우(降雨)(a)(20mm이상이 4시간 지속)에서는 3시간 경과 후에 $1514m^3/hour$, 8월(月) 8일(日)의 강우(降雨)(b)(최대(最大) 시우량(時雨量) 40mm)경우는 동일(同一) 시간대(時間帶)에서 $1246m^3/hour$, 그리고 8월(月) 20일(日)의 강우(降雨)(c)(최대(最大) 시우량(時雨量) 17.2mm)의 경우는 2시간 경과 후에 $1245m^3/hour$의 Peak point가 형성되었다. 2. 임도개설유역(林道開設流域)에서 유출량(流出量)과 부유토사량(浮遊土砂量)의 관계는 유출량(流出量)에 비례하여 부유토사량(浮遊土砂量)도 증가하였다(Table 4 및 Fig. 4). 즉 강우(降雨)(a)는 최대유출량(最大流出量)이 $1514m^3/hour$일 때 부유토사량(浮遊土砂量) 1261mg/l가 1시간 후에 나타났고, 강우(降雨)(b) 및 (c)는 각각 최대유출량(最大流出量) $1246m^3/hour$과 $1245m^3/hour$일 때 최대부유토사량(最大浮遊土砂量) 4952mg/l와 472mg/l가 동일시간대(同一時間帶)에서 나타났다. 3. 강우중(降雨中)의 부유토사량(浮遊土砂量)의 농도(濃度)는 강우강도(降雨强度)에 강하게 영향받고 있으며, 특히 강우강도(降雨强度)가 강할수록 곡선회귀(曲線回歸)의 형태(形態)로 증가하였다. 임도개설유역(林道開設流域)에서의 부유토사농도(浮遊土砂濃度)의 Peak point는 강우(降雨)(a)의 경우 1261mg/l와 125mg/l, 강우(降雨)(b)는 4952mg/l와 44mg/l, 그리고 강우(降雨)(c)는 472mg/l와 4mg/l로서 유역간(流域間)에 현격한 차이가 나타났다.

This study was carried out to clarify the sediment export by measuring suspended solids included in streamflow during the rainy season. The study area is located in Experimental Forests, Kangwon National University, where the forest road is under construction. For this purpose, the forest watershed with construction of forest road was compared with normal forest watershed in amount of rainfall and discharge, suspended solids and discharge, and the amount of rainfall and suspended solids. The results were shown as followings. 1. The relationship of discharge and the amount of rainfall was shown as Table 3 and Fig. 3. The delay time of peak point observed in hydrograph was changed by rainfall intensity and amount of previous rainfall. That is, when there was a rain on 12. Jun(more than 20mm/hour for hours), the peak point began three hours after the rainfall intensity over 20mm/hour, and showed $1514m^3/hour$ in automatic water level recorder. In case of the 8th of Aug.(maximum rainfall intensity: 40mm/hour), the peak point of discharge was $1246m^3/hour$ in the same time with maximum rainfall intensity. And on the 20th of Aug.(the maximum rainfall intensity: 17.2mm/hour), the peak point of discharge was $1245m^3/hour$ two hours after the maximum rainfall intensity. 2. On watershed under forest road construction, the relationship between discharge and suspended solids is that suspended solids was proportionately increased by raising discharge. That is, on the 12th of Jun, the maximum of discharge per hour was $1514m^3/hour$ and 1261mg/l of suspended solids was observed an hour after peak point of discharge. And in case of 8th and 20th Aug., each of peak points is $1246m^3/hour$ and $1245m^3/hour$ by measuring time. The maximums of suspended solids measured within two watersheds were examined in value of 4952mg/l and 472mg/l at the same time. 3. During the rainy season, the concentration of suspended solids was influenced by rainfall intensity and indicated especially curve-regressional increase in case of strong rainfall intensity. In each of watersheds, the maximums of suspended solids were 1261mg/l and 125mg/l, 4952mg/l and 44mg/l, and 472mg/l and 4mg/l by the order of rain(a), (b), and (c). Two watersheds showed a remarkable difference.