Hiroaki NAKAYA
Abstract
Sediment transport process in mountain streams is not entirely controlled by
flow discharge. As a result, the process does not concomitantly follow flow
discharge pattern but shows non]consecutive partly independent dynamism. The
process has been a subject of extensive studies in theoretical, experimental,
as well as observational aspects. Based on direct sampling, experimental bed
load equations have been tested to examine the relationship between flow discharge
and sediment discharge. The sampling and observation efforts led to the development
of more indirect but stable sediment transport monitoring methods (hereafter
gindirect method") in recent years. One of the indirect methods, a hydrophone
sediment discharge measuring system (hereafter ghydrophone system"), has
been intensely studied for the development of practical sediment transport monitoring.
Hydrophone systems have been tested quantitatively in relation to bed load equations
as well as to directly sampled sediment discharge in 100 and 200 km2]scale river
basins.
Quantification efforts have been carried out both as site]specific comparison
between direct and indirect methods, and as a year]long basin]scale examination
utilizing reservoir sedimentation data. These efforts enabled us to take a longer
view than a snap shot view of sediment discharge, which is transported in a
collective form seen as sediment waves. Examination of the extent to which erosion
and flood control structures such as sabo dams transform sediment discharge
of floods has been a major practical concern for a long time. Bed load equations
can analyze the effects of structures at a given moment but are not adequate
to quantify those exerted upon collective forms of sediment discharge. Therefore,
indirect measurement, together with flow discharge observation, was conducted
in an upstream segment of a mountain stream in order to study the transformation
processes and effects of structures. Since direct sampling is not readily possible
in the segment, bed load analytical equations developed in a similar mountain
stream was applied to quantify the sediment transport process in the segment.
The result indicated that sediment discharge flowed down as a wave at a velocity
about one]third of that of average stream flow and that the maximum sediment
discharge did not grow as much as the aggregated sediment discharge of the waves
in the structurally regulated segment of the stream. Flood cases studied here
were minor in their intensities. Further observational efforts and analysis
are needed to examine whether the quantification method is robust enough and
whether the results obtained here hold to a larger flood. This study is a preliminary
attempt to introduce an analytical framework that is applicable to larger flood
cases.
Key wordsFbed load, sediment discharge wave, effects of erosion control structures