Research Article

Measurement and quantification of a sedimentation budget for a reservoir with regular flushing

  1. Margareta B. Jansson*,
  2. Ulf Erlingsson

Article first published online: 20 APR 2000

DOI: 10.1002/(SICI)1099-1646(200005/06)16:3<279::AID-RRR586>3.0.CO;2-S

Issue

Regulated Rivers: Research & Management

Regulated Rivers: Research & Management

Volume 16, Issue 3, pages 279–306, May/June 2000

Additional Information

How to Cite

Jansson, M. B. and Erlingsson, U. (2000), Measurement and quantification of a sedimentation budget for a reservoir with regular flushing. Regulated Rivers: Research & Management, 16: 279–306. doi: 10.1002/(SICI)1099-1646(200005/06)16:3<279::AID-RRR586>3.0.CO;2-S

Author Information

  1. AB Hydroconsult, Drottninggatan 7, S-753 10 Uppsala, Sweden

*AB Hydroconsult, Drottninggatan 7, S-753 10 Uppsala, Sweden

Publication History

  1. Issue published online: 20 APR 2000
  2. Article first published online: 20 APR 2000
  3. Manuscript Accepted: 17 NOV 1999
  4. Manuscript Revised: 10 NOV 1998
  5. Manuscript Received: 16 AUG 1998

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Keywords:

  • bathymetric survey;
  • Costa Rica;
  • density currents;
  • depth survey;
  • reservoir flushing;
  • reservoir sedimentation;
  • sediment budget;
  • sediment load;
  • sediment throughflow;
  • trap efficiency

Abstract

This paper provides a case study of successful removal of reservoir sediment by empty flushing. The main aim of this study was to determine: (i) sediment inflow to the Cachí reservoir; (ii) the pattern and rate of deposition in the reservoir; (iii) the erosion within the reservoir during flushing; and (iv) sediment outflow at a downstream hydrological station during flushing. The results are integrated as a sediment budget for the reservoir. The drainage basin of the Cachí reservoir in Costa Rica is 785 km2.

The sediment budget for the period between two flushings indicates a sediment inflow to the reservoir of c. 930 000 tonnes and a net accumulation of c. 133 000 tonnes, or 14.3% of the sediment inflow. The sediment throughflow was also c. 133 000 tonnes up to the erosion phase of the flushing, and the outflow during flushing including bed load was 663 000 tonnes, i.e. 71.4% of the sediment inflow. Thus, the flushing of the reservoir was highly effective in releasing sediment.

The balance of the sediment budget makes it probable that the major components of the sediment budget are of the right order of magnitude. The main principle to obtain correct sediment loads by the rating-curve technique was to collect sediment data from a large number of storm events at equal time intervals during rising and falling stages. This was achieved by turbidimeter recordings. Because of the wide scatter of data, sediment rating curves were developed on mean sediment loads in discharge classes to avoid the bias of log regressions.

The trap efficiency and sediment throughflow were determined with Sundborg's physically based sedimentation model. The throughflow amounted to 20% of the suspended sediment inflow, which compares well with the empirical budget. The depositional pattern in the Cachí reservoir was surveyed with side-scan sonar, repeated echo-soundings, and by excavating pits in deposits when the reservoir was empty. Deposition occurred mainly in the old river channel, indicating that the major part of the sediment is transported by density currents.

The volume of eroded material in the reservoir during scour valve release was estimated by echo-soundings before and after the flushing. Dry bulk density of the reservoir deposits was determined by X-ray radiographic and densitometric analysis. The radiographic analyses indicated a dry bulk density of 0.4 g cm−3 of the loose material in the thalweg, and 0.7 g cm−3 of the whole deposition depth on the terraces. Copyright © 2000 John Wiley & Sons, Ltd.

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