CIVE 530 - OPEN-CHANNEL HYDRAULICS

LECTURE 17C: SEDIMENTATION ENGINEERING III

17.5  SEDIMENT MEASUREMENT TECHNIQUES

    The measurement of fluvial sediments is often necessary to complement sediment yield and sediment transport studies.

  • The accuracy of the measurement depends on the equipment and techniques, but also on the application of basic principles of sediment transport.

  • As sediment enters a stream, it separates itself into bed-material load and wash load.

  • In turn, the bed-material loal is transported either as bed load or suspended load.

  • The suspended bed-material load plus the wash load constitutes the total suspended load of the stream or river.

  • The term "sampled suspended sediment discharge" is used to describe the fraction of suspended load that can be sampled with available equipment.

  • It excludes the "unsampled suspended sediment discharge," i.e., the fraction of suspended load that is carried too close to the streambed to be effectively sampled.

  • The suspended sediment discharge is the sum of sampled and unsampled suspended sediment discharges.

SEDIMENT-SAMPLING EQUIPMENT

  • Sediment-sampling equipment can be classified as follows:

    1. suspended sediment samplers, which measure suspended sediment concentration;

    2. bed-load samplers, which measure bed load; and

    3. bed-material samplers, which sample the sediment in the top layer of the streambed.
Suspended sediment samplers

  • Suspended sediment samplers can be classified as follows:

    1. depth-integrating,

    2. point-integrating,

    3. single-stage, and

    4. pumping samplers.

  • Depth-integrating samplers accumulate a water-sediment sample in a pint-size milk bottle as they are lowered to the streambed and raised back to the surface at a uniform rate of transit.

  • They are designed so that the velocity in the intake mozzle is nearly equal to the local stream velocity.

  • Samples may be collected by wading in a stream, by hand from a suitable support, or mechanically with a cable-and-reel setup.

  • The DH-48 depth-integrating suspended wading type sampler is shown below.


    DH-48 depth-integrating suspended wading type sampler.

  • With wading-rod suspension, this sampler is used in shallow streams where the product of flow depth (ft) and mean velocity (fps) does not exceed 10.

  • The U.S. DH-59 sampler (24 lb) with handline suspension is used in streams with low velocities but with depths that do not permit samples to be collected by wading.


    DH-59 depth-integrating suspended hand-line sampler.

  • The U.S. D-49 sampler (62 lb) with cable-and-reel suspension is designed for use in streams beyond the range of hand-operated equipment.


    D-49 suspended sediment sampler.

  • Depth-integrating samplers improve sample accuracy and reduce the cost of collecting suspended sediment data.

  • Field data of questionable quality.


  • Point-integrating samplers accumulate a water-sediment sample at any selected point in a stream.

  • A rotary valve is operated by a solenoid to open and close the sampler.

  • These samples can also be used to collect depth-integrating samples by moving it through the vertical.

  • This permits depth integration in streams that are too deep to be sampled with a depth-integrating sampler.

  • The U.S. P-46 and P-61 (100 lb), P-63 (200 lb) and P-50 (300 lb) point-integrating samplers are in current use.


    P-61 suspended sediment sampler.

  • The single-stage sampler was developed to obtain suspended sediment data in flashy streams, particularly those located in remote areas.

  • The pumping sampler is designed to obtain a continuous record of sediment concentration by sampling at a fixed point at specific intervals.

  • This sampler does not require an operator.
Bed load samplers

  • Bed load samplers are of three types:

    1. basket type,

    2. pan type, and

    3. pressure-difference type.

  • The basket and pan types canuse an increase in resistance to flow and a reduction in stream velocity at the sampling location.

  • The reduction in stream velocity interferes with the rate of bed-load transport, compromising the accuracy of the measurement.

  • The pressure-difference bed-load sampler is designed to eliminate the reduction in velocity, increasing accuracy.

  • The efficiency of a bedload sampler is the ratio of sampled bed load to that actually transported.

  • Efficiency varies with sample type, method of support, particle size, and bed configuration.

  • Calibration of bed-load samplers has indicated a mean efficiency of about 45 percent for the basket and pan types, and 70 percent for the pressure-difference type.
Bed-material samplers

  • Bed-material samplers are of three types:

    1. drag bucket,

    2. grab bucket, and

    3. vertical-pipe, or core sampler.

  • The drag bucket sampler consists of a weighted section of cylinder with an open mouth and cutting edge.

  • As the sampler is dragged upstream along the bed, it collects a sample from the top layer of bed material.

  • The grab-bucket smapler is similar to the drag bucket, consisting of a cylinder attached to a rod, and used primarily in shallow streams.

  • The core sampler consists of a piece of metal or plastic pipe that can be forced into the stream by hand.

  • Generally, the drag-bucket and grab-bucket samplers do not obtain fully representatiove samples because of the loss of fine material.

  • The core smapler is satisfactory for use in shallow streams.

  • The U.S. BMH-53 sampler consists of a 9-in long 2-in diameter brass or stainless steel pipe with a cutting edge and suction piston attached to a control rod.


    BMH-53 piston-type bed-material hand sampler.

  • The piston is retracted as the cutting edge is forced into the stream bed.

  • The partial vaccum that develops in the sampling chamber as the piston is withdrawn assists in holding the sample in the cylinder.

  • The sampler can be used only in streams shallow enough to be waded.


  • The U.S. BMH-60 bed material sampler with both handline and cable suspension is designed to scoop up a sample of bed sediment about 3 in wide and 2 in deep.


    BMH-60 handline bed-material sampler.

  • At the close of sampling, the cutting edge rests againts a rubber stop, which prevents any sediment from being lost.

  • The aluminum sampler weighs 30 lb, and the brass sampler 40 lb.

  • It is used to collect bed-material-sediment samples in streams with low velocities but with depths beyond the range of the BHM-53 sampler.


  • The U.S. BM-54 bed-material sampler (100 lb) with cable suspension is similar in design to the BMH-60 sampler.


    BM-54 bed-material sampler.

  • It is used in deep streams where a heavier sampler is necessary.

New samplers

  • The U.S. DH-2 is a bag-type suspended-sediment/water-quality sampler, capable of being used as a hand-line sampler.


    DH-2 suspended sediment sampler.

  • The sampler is designed to meet the requirements of the U.S. Geological Survey for a "clean" suspended-sediment sampler.

  • The sampler will collect at least 1-liter of sample isokinetically to 35 ft.


  • The U.S. D-99 sampler is a bag-type suspended-sediment/water-quality sampler to be used with a suspension reel.


    D-99 suspended sediment/water quality sampler.

  • The sampler weighs 285 pounds and has a streamlined body.

  • The bronze body casting is coated with plastic to reduce the potential for contamination when used for trace element sampling.

SUSPENDED SEDIMENT DISCHARGE MEASUREMENTS

  • Suspended sediment discharge measurements are used to determine sediment concentration at a point in a stream, except for a small unmeasured zone near the streambed.

  • With wading equipment, measurements can generally be made down to within 0.3 ft of the streambed.

  • For cable-supported equipment, the unmeasured zone varies between 0.5 and 1 ft, depending on the size of the sampler used.

  • Suspended sediment discharge measurements include:

    1. suspended sediment concentration,

    2. specific gravity,

    3. temperature of water-sediment mixture,

    4. water discharge, and

    5. distribution of flow in the stream cross section.

  • The streamflow depth and velocity and the facilities at the sampling site (bridge, cableway, and so on) have an influence on the choice of sampler.

  • Stream depth determines whether hand samplers, such as the DH-48 or DH-49, or a cable suspended sampler, such as the D-49, are used.

  • Flow depths over 15 ft require the use of point-integrating samplers to avoid overfilling of the sampling bottles.

  • The larger the product of flow depth times mean velocity, the heavier the sampler required for proper measurement.

  • The number of sampling verticals depends on the desired accuracy and the variation of sediment concentration across the stream.

  • For streams with a stable cross section and essentially uniform sediment concentration across the channel width, sampling at a single vertical is usually adequate.


  • Depth-integrating samplers produce a suspended sediment concentration, which can be measured in parts per million (ppm) and converted to mg/L.

  • The suspended sediment discharge is given by the following formula:

    Qs = 0.0027 Cs Q

    in which

    Qs = suspended sediment discharge, in tons/day;

    Cs = suspended sediment concentration, in mg/L;

    Q = water discharge, in cfs; and

    The quantity 0.0027 is conversion factor for the indicated units (U.S. Customary).


Measurements of suspended sediment discharge

  • There are two techniques to measure suspended sediment discharge:

    1. EDI, or equal-discharge increment, and

    2. ETR, or equal-transit rate.

  • In the EDI method, sampling is done at the centroid of equal-discharge increments.

  • In the ETR method, sampling is done at the centroid of equal-length increments.

  • The EDI method requires a knowledge of the lateral distribution of streamflow prior to the selection of sampling verticals.

  • The ETR method is applicable to shallow streams where the cross sectional distribution of streamflow is not stable.

  • Generally, the EDI method requires fewer sampling verticals that the ETR method.

  • However, the ETR method does not require a prior discharge measurement.

  • In the EDI method, the suspended sediment concentration is the average obtained from several depth-integrating samples.

  • In the ETR method, the suspended sediment concentration is that of a composite sample encompassing several depth-integrating samples.


  • The error in suspended sediment discharge provided by the measurement varies with the depth of the unsampled zone and the size distribution of suspended load.

  • The error tends to be smallest in the cases where the vertical concentration gradient in the unsampled zone is small.

  • The concentration gradient near the bed is small for silt and clay particles, and large for the coarser sand particles.

  • Corrections in sampled suspended-sediment discharge to account for the unsampled portion are usually obtained through appropriate sediment transport predictors such as the Colby 1957 method or the Modified Einstein Procedure.

 
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