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A Comparative Study on the Spacing and Discharge Performance of Subsurface Drainage Culvert to Increase Drainage Efficiency

배수효율이 높은 지하암거의 간격과 주름유공관의 통수능 비교분석

  • KIM, Hyuntai (Mirae Rural Technology Institute) ;
  • RYU, Jeonyong (Rural Research Institute, Korea Rural Community Corporation) ;
  • JUNG, Kiyuol (National Institute of Crop Science, Rural Development Administration) ;
  • PARK, Youngjun (Rural Research Institute, Korea Rural Community Corporation)
  • Received : 2019.10.07
  • Accepted : 2019.10.29
  • Published : 2019.11.30

Abstract

This study compared the theory of a culvert spacing and analytical results of the seepage flow for the subsurface drainage. i) If culvert spacing (Sc) is within 5 m, the unit drainage (q) is very larger; in contrast, if Sc is 5 m or more, there is very little drainage in the middle between drains. Therefore, the drain spacing should be within 5 m to ensure high drainage efficiency. ii) Since the planned culvert drainage increases linearly with the soil's permeability coefficient (k), k must be taken into account when determining the drain diameter by the planned culvert drainage. iii) As a result of analyzing the drainage performance of the absorbing culvert, the drainage performance is sufficient with the diameter of the corrugated drain pipe Dc = 50 mm at the length of the drain Lc = 100 m. iv) Therefore, if the drain spacing (Sc) is less than 5 m using the low-cost non-excavated drainage pipe method (${\Phi}50mm$ the corrugated drain pipe and fiber mat) rather than the conventional trench drain method (Sc > 10 m, Dc > 100 mm), uniform and high drainage efficiency can be ensured as well as low construction cost. v) The sub-irrigation+drainage culvert requires narrower drain spacing (Sc < 2-3 m) for irrigation. As a result of examining the condition of 35 mm in diameter (Dc) and 2~3 m in drain spacing, it is possible to apply the non-excavated drainage pipe method to the sub-irrigation+drainage culvert because drainage performance is sufficient at the drain length Lc = 50 m.

Keywords

References

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