Difference between revisions of "USP-61 suspended load sampler"

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==USP-61 point-integrating sampler==
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This article is a summary of sub-section 5.6.2.4 of the [[Manual Sediment Transport Measurements in Rivers, Estuaries and Coastal Seas]]<ref>Rijn, L. C. van (1986). ''Manual sediment transport measurements''. Delft, The Netherlands: Delft Hydraulics Laboratory</ref>. This article describes how the USP-61 can be used to determine silt and/or sand concentrations. The USP-61 is an example of a mechanical instrument.
  
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==Introduction==
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[[Image:H5624figure1.jpg|thumb|250px|right|Figure 1: USP-61 sampler]]
 
The sampler consists of a streamlined bronze casting (= 50 kg), which encloses a small bottle (= 500 ml), as shown in Figure 1A. The sampler head is hinged to provide access to the bottle. The intake nozzle, which can be opened or closed by means of an electrically operated valve, points directly into the approaching flow.
 
The sampler consists of a streamlined bronze casting (= 50 kg), which encloses a small bottle (= 500 ml), as shown in Figure 1A. The sampler head is hinged to provide access to the bottle. The intake nozzle, which can be opened or closed by means of an electrically operated valve, points directly into the approaching flow.
To eliminate a sudden inrush after opening of the intake nozzle, the air pressure in the bottle is balanced with the hydrostatic pressure prior to opening of the valve. This is accomplished by means of an air bell in a body cavity connecting the bottle and the surrounding stream. After opening of the valve, the air in the bottle can escape through a special air-exhaust tube pointing downstream on the side of the sampler head. As a result the hydraulic coefficient is approximately unity during sampling. The filling time varies from 10 to 30 seconds, as shown in Figure 1B. To avoid a circulation flow, the bottle should only be filled for about 75%. The USP-63 is a heavier version (= 100 kg) of the USP-61. The sampler is manufactured by Rickly Hydrological Company (www.rickly.com).
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To eliminate a sudden inrush after opening of the intake nozzle, the air pressure in the bottle is balanced with the hydrostatic pressure prior to opening of the valve. This is accomplished by means of an air bell in a body cavity connecting the bottle and the surrounding stream. After opening of the valve, the air in the bottle can escape through a special air-exhaust tube pointing downstream on the side of the sampler head. As a result the hydraulic coefficient is approximately unity during sampling. The filling time varies from 10 to 30 seconds, as shown in Figure 1B. To avoid a circulation flow, the bottle should only be filled for about 75%. The USP-63 is a heavier version (= 100 kg) of the USP-61. The sampler is manufactured by [http://www.rickly.com Rickly Hydrological Company].
  
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==Determination of silt and sand concentrations==
 
The silt and sand concentrations are determined as:
 
The silt and sand concentrations are determined as:
  
c=G/V
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<math>c\,=G\,/V\,</math>
  
in which: G= dry mass of sediment (mg), V= volume of water sample (l).
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in which: <math>G</math>= dry mass of sediment (mg), <math>V</math>= volume of water sample (l).
  
 
The silt and sand transport (in kg/s/m<sup>2</sup>) can be determined as:
 
The silt and sand transport (in kg/s/m<sup>2</sup>) can be determined as:
  
S=G/(F T)
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<math>S = \large\frac{G}{FT}</math>,
  
in which: F= area of nozzle (m<sup>2</sup>), T= sampling period (s).
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in which: <math>F</math>= area of nozzle (m<sup>2</sup>), <math>T</math>= sampling period (s).
  
 
The sampling efficiency of the USP-61 is strongly dependent on the ratio of the intake velocity and the local flow velocity (hydraulic coefficient).
 
The sampling efficiency of the USP-61 is strongly dependent on the ratio of the intake velocity and the local flow velocity (hydraulic coefficient).
Extensive laboratory measurements, summarized by '''Dijkman (1978)''', have shown that the hydraulic coefficient varies from about 0.8 to 1.3 depending on the water temperature, sample height above the bed and the nozzle orientation (maximum deviation with flow direction of 20°). For this range a maximum sampling error in the concentration of about 10% may be expected in case of a steady concentration. In the case of field conditions with fluctuating concentrations  the  inaccuracy of  individual  samples may be as large as 50%. To obtain a reliable average value in a statistical sense, a large number of samples  (about 10) should be collected at each sampling point.
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Extensive laboratory measurements, summarized by Dijkman (1978)<ref>
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Dijkman, J.(1978) ''Some Characteristics of  the USP-61 and Delft Bottle''. Delft University of Technology,  Dep. of Civ.  Eng., Int. Report No. 5- 78, The Netherlands.</ref>, have shown that the hydraulic coefficient varies from about 0.8 to 1.3 depending on the water temperature, sample height above the bed and the nozzle orientation (maximum deviation with flow direction of 20°). For this range a maximum sampling error in the concentration of about 10% may be expected in case of a steady concentration. In the case of field conditions with fluctuating concentrations  the  inaccuracy of  individual  samples may be as large as 50%. To obtain a reliable average value in a statistical sense, a large number of samples  (about 10) should be collected at each sampling point.
  
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==See also==
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===Summaries of the manual===
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* [[Manual Sediment Transport Measurements in Rivers, Estuaries and Coastal Seas]]
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* Chapter 1: [[Introduction, problems and approaches in sediment transport measurements]]
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* Chapter 2:  [[Definitions, processes and models in morphology]]
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* Chapter 3: [[Principles, statistics and errors of measuring sediment transport]]
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* Chapter 4: [[Computation of sediment transport and presentation of results]]
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* Chapter 5: [[Measuring instruments for sediment transport]]
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* Chapter 6: [[Measuring instruments for particle size and fall velocity]]
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* Chapter 7: [[Measuring instruments for bed material sampling]]
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* Chapter 8: [[Laboratory and in situ analysis of samples]]
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* Chapter 9: [[In situ measurement of wet bulk density]]
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* Chapter 10: [[Instruments for bed level detection]]
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* Chapter 11: [[Argus video]]
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* Chapter 12: [[Measuring instruments for fluid velocity, pressure and wave height]]
  
==References==
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===Other internal links===
 
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* [[Bottle and trap samplers]]
'''Dijkman, J., 1978'''. Some Characteristics of  the USP-61 and Delft Bottle. Delft University of Technology,  Dep. of Civ.  Eng., Int. Report No. 5- 78, The Netherlands.
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* [[Delft Bottle suspended load sampler]]
 
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* [[Pump samplers]]
'''Dijkman,  J.P.M.  and Milisic, V., 1982'''. Investigations on Suspended Sediment Samplers. Delft Hydraulics Laboratory and Jaroslav Cerni  Institute,  Report S410, The Netherlands.
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* [[Sand transport]]
 
 
'''FEDERAL INTER-AGENCY SEDIMENTATION PROJECT'''. Instructions for USP-61, Suspended Sediment Sampler Minnesota 5541K, U.S.A.
 
  
  
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===Further reading===
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* Dijkman,  J.P.M.  and Milisic, V. (1982) ''Investigations on Suspended Sediment Samplers''. Delft Hydraulics Laboratory and Jaroslav Cerni  Institute,  Report S410, The Netherlands.
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* FEDERAL INTER-AGENCY SEDIMENTATION PROJECT. ''Instructions for USP-61, Suspended Sediment Sampler''. Minnesota 5541K, U.S.A.
  
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==References==
 
<references/>
 
<references/>
 
==See also==
 
 
===Other contributions of Leo van Rijn===
 
 
====articles with parts of the manual====
 
*[[Manual Sediment Transport Measurements in Rivers, Estuaries and Coastal Seas]]
 
 
*[[INTRODUCTION, PROBLEMS AND APPROACHES IN SEDIMENT TRANSPORT MEASUREMENTS]]
 
*[[DEFINITIONS, PROCESSES AND MODELS IN MORPHOLOGY]]
 
*[[PRINCIPLES, STATISTICS AND ERRORS OF MEASURING SEDIMENT TRANSPORT]]
 
*[[COMPUTATION OF SEDIMENT TRANSPORT AND PRESENTATION OF RESULTS]]
 
*[[MEASURING INSTRUMENTS FOR SEDIMENT TRANSPORT]]
 
*[[MEASURING INSTRUMENTS FOR PARTICLE SIZE AND FALL VELOCITY]]
 
*[[MEASURING INSTRUMENTS FOR BED MATERIAL SAMPLING]]
 
*[[LABORATORY AND IN-SITU ANALYSIS OF SAMPLES]]
 
*[[IN-SITU MEASUREMENT OF WET BULK DENSITY]]
 
*[[INSTRUMENTS FOR BED LEVEL DETECTION]]
 
*[[ARGUS VIDEO]]
 
*[[MEASURING  INSTRUMENTS FOR FLUID VELOCITY, PRESSURE AND WAVE HEIGHT]]
 
 
 
==External links==
 
 
www.rickly.com[http://www.rickly.com]
 
 
==Crediting the authors==
 
 
  
 
{{author  
 
{{author  
 
|AuthorID=13226  
 
|AuthorID=13226  
|AuthorName= Rijn, Leo van}}
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|AuthorFullName= Rijn, Leo van
 
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|AuthorName=Leovanrijn}}
  
 
{{author  
 
{{author  
 
|AuthorID=12969  
 
|AuthorID=12969  
|AuthorName= Roberti, Hans}}
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|AuthorFullName= Roberti, Hans
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|AuthorName=Robertihans}}
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[[Category:Coastal and marine observation and monitoring]]
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[[Category:Observation of physical parameters]]

Latest revision as of 16:07, 23 August 2020

This article is a summary of sub-section 5.6.2.4 of the Manual Sediment Transport Measurements in Rivers, Estuaries and Coastal Seas[1]. This article describes how the USP-61 can be used to determine silt and/or sand concentrations. The USP-61 is an example of a mechanical instrument.

Introduction

Figure 1: USP-61 sampler

The sampler consists of a streamlined bronze casting (= 50 kg), which encloses a small bottle (= 500 ml), as shown in Figure 1A. The sampler head is hinged to provide access to the bottle. The intake nozzle, which can be opened or closed by means of an electrically operated valve, points directly into the approaching flow. To eliminate a sudden inrush after opening of the intake nozzle, the air pressure in the bottle is balanced with the hydrostatic pressure prior to opening of the valve. This is accomplished by means of an air bell in a body cavity connecting the bottle and the surrounding stream. After opening of the valve, the air in the bottle can escape through a special air-exhaust tube pointing downstream on the side of the sampler head. As a result the hydraulic coefficient is approximately unity during sampling. The filling time varies from 10 to 30 seconds, as shown in Figure 1B. To avoid a circulation flow, the bottle should only be filled for about 75%. The USP-63 is a heavier version (= 100 kg) of the USP-61. The sampler is manufactured by Rickly Hydrological Company.

Determination of silt and sand concentrations

The silt and sand concentrations are determined as:

[math]c\,=G\,/V\,[/math]

in which: [math]G[/math]= dry mass of sediment (mg), [math]V[/math]= volume of water sample (l).

The silt and sand transport (in kg/s/m2) can be determined as:

[math]S = \large\frac{G}{FT}[/math],

in which: [math]F[/math]= area of nozzle (m2), [math]T[/math]= sampling period (s).

The sampling efficiency of the USP-61 is strongly dependent on the ratio of the intake velocity and the local flow velocity (hydraulic coefficient). Extensive laboratory measurements, summarized by Dijkman (1978)[2], have shown that the hydraulic coefficient varies from about 0.8 to 1.3 depending on the water temperature, sample height above the bed and the nozzle orientation (maximum deviation with flow direction of 20°). For this range a maximum sampling error in the concentration of about 10% may be expected in case of a steady concentration. In the case of field conditions with fluctuating concentrations the inaccuracy of individual samples may be as large as 50%. To obtain a reliable average value in a statistical sense, a large number of samples (about 10) should be collected at each sampling point.

See also

Summaries of the manual

Other internal links


Further reading

  • Dijkman, J.P.M. and Milisic, V. (1982) Investigations on Suspended Sediment Samplers. Delft Hydraulics Laboratory and Jaroslav Cerni Institute, Report S410, The Netherlands.
  • FEDERAL INTER-AGENCY SEDIMENTATION PROJECT. Instructions for USP-61, Suspended Sediment Sampler. Minnesota 5541K, U.S.A.

References

  1. Rijn, L. C. van (1986). Manual sediment transport measurements. Delft, The Netherlands: Delft Hydraulics Laboratory
  2. Dijkman, J.(1978) Some Characteristics of the USP-61 and Delft Bottle. Delft University of Technology, Dep. of Civ. Eng., Int. Report No. 5- 78, The Netherlands.
The main author of this article is Rijn, Leo van
Please note that others may also have edited the contents of this article.

Citation: Rijn, Leo van (2020): USP-61 suspended load sampler. Available from http://www.coastalwiki.org/wiki/USP-61_suspended_load_sampler [accessed on 25-11-2024]


The main author of this article is Roberti, Hans
Please note that others may also have edited the contents of this article.

Citation: Roberti, Hans (2020): USP-61 suspended load sampler. Available from http://www.coastalwiki.org/wiki/USP-61_suspended_load_sampler [accessed on 25-11-2024]