ASTM D7512-09(2015)
(Guide)Standard Guide for Monitoring of Suspended-Sediment Concentration in Open Channel Flow Using Optical Instrumentation
Standard Guide for Monitoring of Suspended-Sediment Concentration in Open Channel Flow Using Optical Instrumentation
SIGNIFICANCE AND USE
5.1 This guide is general and intended as a planning guide. To satisfactorily monitor a specific site, an investigator must sometimes design specific installation structures or modify those given in this guide to meet the requirements of the site in question. Because of the dynamic nature of the sediment transport process, the extent to which characteristics such as mass concentration and particle-size distribution are accurately represented in the monitoring program depends on the type of equipment used and method of collection of the SSC samples used to calibrate the optical readings. Sediment concentration is highly variable in both time and space. Numerous samples must be collected and analyzed with proper equipment and standardized methods for the rating of the optical equipment at a particular site (see Guide D4411 and Practice D3977).
5.2 All optical equipment have an upper limit for valid readings, beyond which the meter will not read properly, commonly referred to as “blacking out.” If upper range of SSC are expected to cause optical instrument black out, then some other means should be devised, such as automatic pumping samplers, to collect samples during this period. See Edwards and Glysson (1)3 and Glysson (2) for information on collection of suspended sediment samples using pumping samplers. It should be noted that other technologies, such as lasers and acoustic dopplers, are also being used to monitor SSC continuously.
5.3 The user of this guide should realize that because different technologies and different models of the same technology of turbidity meters can produce significantly different outputs for the same environmental sample, only one manufacturer and model of the turbidity meter can be used to develop the relationship between the SSC and turbidity readings at a site. If a different manufacturer or a different model type of turbidity meter is used, a new relationship will need to be develop for the site.
SCOPE
1.1 This guide covers the equipment and basic procedures for installation, operation, and calibration of optical equipment as a surrogate for the continuous determination of suspended-sediment concentration (SSC) in open channel flow.
1.2 This guide emphasizes general principles for the application of optical measurements to be used to estimate suspended-sediment concentration (SSC) in water. Only in a few instances are step-by-step instructions given. Continuous monitoring is a field-based operation, methods and equipment are usually modified to suit local conditions. The modification process depends upon the operator skill and judgment.
1.3 This guide covers the use of the output from an optical instrument, such as turbidity and suspended-solids meters, to record data that can be correlated with suspended-sediment concentration. It does not cover the process of collecting data for continuous turbidity record, which would require additional calibration of the turbidity readings to the mean turbidity of the measurement cross section. For the purposes of this method it is assumed that the dependent variable will be mean cross-sectional suspended-sediment concentration data.
1.4 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.
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This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the
Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
Designation: D7512 − 09 (Reapproved 2015)
Standard Guide for
Monitoring of Suspended-Sediment Concentration in Open
Channel Flow Using Optical Instrumentation
This standard is issued under the fixed designation D7512; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 2. Referenced Documents
1.1 This guide covers the equipment and basic procedures 2.1 ASTM Standards:
for installation, operation, and calibration of optical equipment D3977 Test Methods for Determining Sediment Concentra-
as a surrogate for the continuous determination of suspended- tion in Water Samples
sediment concentration (SSC) in open channel flow. D4411 Guide for Sampling Fluvial Sediment in Motion
D7315 Test Method for Determination of TurbidityAbove 1
1.2 This guide emphasizes general principles for the appli-
Turbidity Unit (TU) in Static Mode
cation of optical measurements to be used to estimate
suspended-sediment concentration (SSC) in water. Only in a
3. Terminology
few instances are step-by-step instructions given. Continuous
3.1 Definitions:
monitoring is a field-based operation, methods and equipment
3.1.1 calibration drift, n—the error that is the result of drift
are usually modified to suit local conditions. The modification
in the sensor reading from the last time the sensor was
process depends upon the operator skill and judgment.
calibrated, and is determined by the difference between
1.3 This guide covers the use of the output from an optical
cleaned-sensor readings in calibration standards and the true,
instrument, such as turbidity and suspended-solids meters, to
temperature-compensated value of the calibration standards.
record data that can be correlated with suspended-sediment
3.1.2 continuous, adj—refers to a time series of unit values
concentration. It does not cover the process of collecting data
that are close enough in time to simulate a continuous record.
forcontinuousturbidityrecord,whichwouldrequireadditional
3.1.2.1 Discussion—Generally, in studies of open-channel
calibrationoftheturbidityreadingstothemeanturbidityofthe
flow, 15-minute intervals are used and are adequate to esti-
measurement cross section. For the purposes of this method it
mated continuous record. However, the time interval maybe as
is assumed that the dependent variable will be mean cross-
little as a minute or as great as an hour.
sectional suspended-sediment concentration data.
3.1.3 fouling, n—the error that can result from a variety of
1.4 The values stated in SI units are to be regarded as
sources (such as biological growth on the sonde and covering
standard. No other units of measurement are included in this
of the probe with sediment), and is determined by the differ-
standard.
ence between sensor measurements in the environment before
1.5 This standard does not purport to address all of the
and after the sensors are cleaned.
safety concerns, if any, associated with its use. It is the
3.1.4 sonde, n—part of the monitoring equipment that con-
responsibility of the user of this standard to establish appro-
tains the measurement sensors.
priate safety, health, and environmental practices and deter-
3.1.4.1 Discussion—A sonde may be either a single param-
mine the applicability of regulatory limitations prior to use.
eter sensor or a combination of different sensors of different
1.6 This international standard was developed in accor-
parameters.
dance with internationally recognized principles on standard-
ization established in the Decision on Principles for the
4. Summary of Guide
Development of International Standards, Guides and Recom-
4.1 This guide covers the equipment and basic procedures
mendations issued by the World Trade Organization Technical
for installation, operation, and calibration of optical equipment
Barriers to Trade (TBT) Committee.
as a surrogate for the continuous or near continuous determi-
nation of SSC in open channel flow.
This practice is under the jurisdiction of ASTM Committee D19 on Water and
is the direct responsibility of Subcommittee D19.07 on Sediments, Geomorphology,
and Open-Channel Flow. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Current edition approved Jan. 15, 2015. Published February 2015. Originally contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
approved in 2009. Last previous edition approved in 2009 as D7512 – 09. DOI: Standards volume information, refer to the standard’s Document Summary page on
10.1520/D7512-09R15. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
D7512 − 09 (2015)
4.2 This guide emphasizes general principles for one par- 6.2.1 The Alliance for Coastal Techniologies (ACT) did an
ticular application of optical measurements in water. This in-situevaluationofdifferentnephelometertechnologist.Users
guide covers the use of nephelometers and backscatter type ofthisguidemaybeinterestedintheresultsofthisstudywhich
turbidity meters to record data that can be correlated with SSC. can be found online.
6.3 Before selecting the type of meter to be used, the
5. Significance and Use
operator needs to review the site requirements in order to
ensure selection of the proper instrumentation. Things to
5.1 This guide is general and intended as a planning guide.
consider, but are not limited to, are: the instruments ability to
To satisfactorily monitor a specific site, an investigator must
survive the study site environment, the degree of fouling that
sometimes design specific installation structures or modify
may take place, and the range of readings likely to be
those given in this guide to meet the requirements of the site in
encountered at the site.
question. Because of the dynamic nature of the sediment
transport process, the extent to which characteristics such as
6.4 If a flow-through or in-situ monitoring device is used, a
mass concentration and particle-size distribution are accurately
recording system must be installed.The recording system must
represented in the monitoring program depends on the type of
have enough storage capacity to store all data recorded
equipment used and method of collection of the SSC samples
between site service visits. See manufacturer’s advice on
used to calibrate the optical readings. Sediment concentration
which recording devices will work best for the type of monitor
is highly variable in both time and space. Numerous samples
being used.
must be collected and analyzed with proper equipment and
6.5 Remote access and near real-time transmission of data
standardized methods for the rating of the optical equipment at
from the site to the office can be very important in meeting the
a particular site (see Guide D4411 and Practice D3977).
objectives of the monitoring station. Remote access and the
5.2 All optical equipment have an upper limit for valid near real-time transmittal of the recorded data take other
equipment (such as a data collection platform (DCP), and
readings, beyond which the meter will not read properly,
commonly referred to as “blacking out.” If upper range of SSC transmittal antenna) in addition to the optical sensor. A DCP
performs the same fundamental function as a basic data
are expected to cause optical instrument black out, then some
other means should be devised, such as automatic pumping recorder (BDR). They both collect data from attached sensors
on a timed interval and store the results. The difference is the
samplers, to collect samples during this period. See Edwards
and Glysson (1) and Glysson (2) for information on collection BDR retains the data until it is retrieved manually, while the
of suspended sediment samples using pumping samplers. It DCP has the ability to transmit the collected data to another
should be noted that other technologies, such as lasers and location. Since data is transferred elsewhere for storage shortly
acoustic dopplers, are also being used to monitor SSC continu- after collection, a DCP may have less memory than a BDR.
ously. The data may be transmitted via telephone modem, line-of-site
radio link or satellite. It is beyond the scope of this guide to
5.3 The user of this guide should realize that because
discuss how to instrument a site for remote data transmission
different technologies and different models of the same tech-
and no single reference on how to do this is available for
nology of turbidity meters can produce significantly different
reference here. The user is encouraged to visit the U.S.
outputs for the same environmental sample, only one manu-
Geological Survey’s Hydrologic Instrumentation Facility web-
facturer and model of the turbidity meter can be used to
site for information on equipment needs and used by the
develop the relationship between the SSC and turbidity read-
USGS.
ings at a site. If a different manufacturer or a different model
6.6 The installation of an automatic pumping sampler,
type of turbidity meter is used, a new relationship will need to
especially in remote areas, will allow samples to be collected
be develop for the site.
that can be used to relate the optical reading to the suspended-
sediment concentration in the stream and also address the
6. Apparatus
blackout periods discussed in 5.2. Detailed information con-
6.1 In general, three types of configurations of installations
cerning the installation and operation of pumping samplers is
of monitors can be used: (1) the flow-through monitoring
beyond the scope of this guide. See Edwards and Glysson (1)
system, (2) the in-situ monitoring system, and (3) the self
and Glysson (2) for more information on the use of automatic
contained, combined sensor and recording system.
pumping samplers.
6.2 Optical instruments such as photoelectric nephelometer
7. Site Selection
(best used for lower levels of SSC) and backscatter sensors
(best used for higher levels of SSC) provide the basis for this
7.1 The procedure for establishing a sampling location
method. For more information concerning the advantages and
should emphasize the quest for a stream-data site. A stream-
disadvantages of each, see Test Method D7315. As they
data site is as a cross section displaying relatively stable
become available, other sensors may be used.
hydrologic characteristics and uniform depths over a wide
3 4
The boldface numbers in parentheses refer to a list of references at the end of Available from http://www.act-us.info/evaluation.php.
this standard. Available from http://water.usgs.gov/hif.
D7512 − 09 (2015)
range of stream discharges, from which representative sedi- given stream conditions at one stage would produce the same
ment data can be obtained and related to a stage-discharge sampling point location relative to the flow conditions at a
rating and optical readings from the site. This is an idealized different stage. Therefore, generalized guidelines (modified
concept because the perfect site is rare at best. Therefore, it is from (1)) are outlined here and should be considered on a
necessary to note the limitations of the most suitable site case-by-case basis when selecting a sampling point.
available and build a program to minimize the disadvantages 8.1.1 Select a stable cross section of reasonably uniform
and maximize the advantages. depth and width to maximize the stability of the relationship
between sediment concentration at a point and the mean
7.2 Sites that may be affected by backwater conditions
sedimentconcentrationinthecrosssection.Thisguidelineisof
should be avoided whenever possible. Backwater condition is
primary importance in the decision to use an optical meter in a
a transient condition that occurs when water is backed up or
given situation; if a reasonably stable relation between the
retarded in a stream by tides or from inflow from another
sample-point reading and mean cross-section concentration
stream. Backwater affects both stage-discharge and velocity-
cannot be attained by the following outlined steps, the meter
discharge relationships.Therefore, a given discharge may have
should not be installed and an alternate location considered.
varying stage and mean stream velocity and thus have varying
8.1.2 Consider only the part of the vertical that could be
sediment transport rates.
sampled using a standard U.S. depth- or point-integrating
7.3 Asediment-measuringsitelocateddownstreamfromthe
suspended-sediment sampler, excluding the unsampled zone,
confluence of two streams may require extra sediment mea-
because data collected with a depth- or point-integrating
surements due to incomplete mixing of the flows from the
sampler will be used to calibrate the optical meter. See Guide
tributaries. Moving the sampling location far enough down-
D4411 and Edwards and Glysson (1) for information on the
stream to ensure adequate mixing of the tributary flows should
unsampled zone, proper procedures, and equipment to collect
be investigated.
samples for SSC analysis.
7.4 Because sediment samples must be obtained more 8.1.3 Determine, if possible, the depth of the point of mean
frequently during high flows, and it is imperative that a site be sediment concentration in each vertical for each size class of
selected where obtaining data during these times are feasible. particles finer than 0.250 mm, from a series of carefully
Particular attention should be given to the ease of access to the collected point integrated samples. See Edwards and Glysson
water-stage recorder and to a usable bridge or cable during (1) for information on the collection of point samples and Guy
(5) for procedures for determining particle size of sediment
high flows, many of which occur at night. Sites accessible only
by poorly maintained backroads or trails should be avoided. samples.
8.1.4 Determine, if possible, the mean depth of occurrence
7.5 The average monitoring site will consist of a shelter to
of the mean sediment concentration in each vertical for all
house and protect the equipment and some means for either
particles finer than 0.250 mm.
bringing water to the meters or conduits that will allow the
8.1.5 Use the mean depth of occurrence of the mean
meter to be placed in the flow zone of the channel. The shelter
sedimentconcentrationinthecrosssectionasareferencedepth
should be located to minimize the distance between the stream
for placem
...
NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
Contact ASTM International (www.astm.org) for the latest information
Designation: D7512 − 09 (Reapproved 2015)
Standard Guide for
Monitoring of Suspended-Sediment Concentration in Open
Channel Flow Using Optical Instrumentation
This standard is issued under the fixed designation D7512; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 2. Referenced Documents
1.1 This guide covers the equipment and basic procedures 2.1 ASTM Standards:
for installation, operation, and calibration of optical equipment D3977 Test Methods for Determining Sediment Concentra-
as a surrogate for the continuous determination of suspended- tion in Water Samples
sediment concentration (SSC) in open channel flow. D4411 Guide for Sampling Fluvial Sediment in Motion
D7315 Test Method for Determination of Turbidity Above 1
1.2 This guide emphasizes general principles for the appli-
Turbidity Unit (TU) in Static Mode
cation of optical measurements to be used to estimate
suspended-sediment concentration (SSC) in water. Only in a
3. Terminology
few instances are step-by-step instructions given. Continuous
3.1 Definitions:
monitoring is a field-based operation, methods and equipment
3.1.1 calibration drift, n—the error that is the result of drift
are usually modified to suit local conditions. The modification
in the sensor reading from the last time the sensor was
process depends upon the operator skill and judgment.
calibrated, and is determined by the difference between
1.3 This guide covers the use of the output from an optical
cleaned-sensor readings in calibration standards and the true,
instrument, such as turbidity and suspended-solids meters, to
temperature-compensated value of the calibration standards.
record data that can be correlated with suspended-sediment
3.1.2 continuous, adj—refers to a time series of unit values
concentration. It does not cover the process of collecting data
that are close enough in time to simulate a continuous record.
for continuous turbidity record, which would require additional
3.1.2.1 Discussion—Generally, in studies of open-channel
calibration of the turbidity readings to the mean turbidity of the
flow, 15-minute intervals are used and are adequate to esti-
measurement cross section. For the purposes of this method it
mated continuous record. However, the time interval maybe as
is assumed that the dependent variable will be mean cross-
little as a minute or as great as an hour.
sectional suspended-sediment concentration data.
3.1.3 fouling, n—the error that can result from a variety of
1.4 The values stated in SI units are to be regarded as
sources (such as biological growth on the sonde and covering
standard. No other units of measurement are included in this
of the probe with sediment), and is determined by the differ-
standard.
ence between sensor measurements in the environment before
1.5 This standard does not purport to address all of the
and after the sensors are cleaned.
safety concerns, if any, associated with its use. It is the
3.1.4 sonde, n—part of the monitoring equipment that con-
responsibility of the user of this standard to establish appro-
tains the measurement sensors.
priate safety, health, and environmental practices and deter-
3.1.4.1 Discussion—A sonde may be either a single param-
mine the applicability of regulatory limitations prior to use.
eter sensor or a combination of different sensors of different
1.6 This international standard was developed in accor-
parameters.
dance with internationally recognized principles on standard-
ization established in the Decision on Principles for the
4. Summary of Guide
Development of International Standards, Guides and Recom-
4.1 This guide covers the equipment and basic procedures
mendations issued by the World Trade Organization Technical
for installation, operation, and calibration of optical equipment
Barriers to Trade (TBT) Committee.
as a surrogate for the continuous or near continuous determi-
nation of SSC in open channel flow.
This practice is under the jurisdiction of ASTM Committee D19 on Water and
is the direct responsibility of Subcommittee D19.07 on Sediments, Geomorphology,
and Open-Channel Flow. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Current edition approved Jan. 15, 2015. Published February 2015. Originally contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
approved in 2009. Last previous edition approved in 2009 as D7512 – 09. DOI: Standards volume information, refer to the standard’s Document Summary page on
10.1520/D7512-09R15. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
D7512 − 09 (2015)
4.2 This guide emphasizes general principles for one par- 6.2.1 The Alliance for Coastal Techniologies (ACT) did an
ticular application of optical measurements in water. This in-situ evaluation of different nephelometer technologist. Users
guide covers the use of nephelometers and backscatter type of this guide may be interested in the results of this study which
turbidity meters to record data that can be correlated with SSC. can be found online.
6.3 Before selecting the type of meter to be used, the
5. Significance and Use
operator needs to review the site requirements in order to
ensure selection of the proper instrumentation. Things to
5.1 This guide is general and intended as a planning guide.
consider, but are not limited to, are: the instruments ability to
To satisfactorily monitor a specific site, an investigator must
survive the study site environment, the degree of fouling that
sometimes design specific installation structures or modify
may take place, and the range of readings likely to be
those given in this guide to meet the requirements of the site in
encountered at the site.
question. Because of the dynamic nature of the sediment
transport process, the extent to which characteristics such as
6.4 If a flow-through or in-situ monitoring device is used, a
mass concentration and particle-size distribution are accurately
recording system must be installed. The recording system must
represented in the monitoring program depends on the type of
have enough storage capacity to store all data recorded
equipment used and method of collection of the SSC samples
between site service visits. See manufacturer’s advice on
used to calibrate the optical readings. Sediment concentration
which recording devices will work best for the type of monitor
is highly variable in both time and space. Numerous samples
being used.
must be collected and analyzed with proper equipment and
6.5 Remote access and near real-time transmission of data
standardized methods for the rating of the optical equipment at
from the site to the office can be very important in meeting the
a particular site (see Guide D4411 and Practice D3977).
objectives of the monitoring station. Remote access and the
near real-time transmittal of the recorded data take other
5.2 All optical equipment have an upper limit for valid
readings, beyond which the meter will not read properly, equipment (such as a data collection platform (DCP), and
transmittal antenna) in addition to the optical sensor. A DCP
commonly referred to as “blacking out.” If upper range of SSC
are expected to cause optical instrument black out, then some performs the same fundamental function as a basic data
recorder (BDR). They both collect data from attached sensors
other means should be devised, such as automatic pumping
samplers, to collect samples during this period. See Edwards on a timed interval and store the results. The difference is the
and Glysson (1) and Glysson (2) for information on collection BDR retains the data until it is retrieved manually, while the
of suspended sediment samples using pumping samplers. It DCP has the ability to transmit the collected data to another
should be noted that other technologies, such as lasers and location. Since data is transferred elsewhere for storage shortly
acoustic dopplers, are also being used to monitor SSC continu- after collection, a DCP may have less memory than a BDR.
ously. The data may be transmitted via telephone modem, line-of-site
radio link or satellite. It is beyond the scope of this guide to
5.3 The user of this guide should realize that because
discuss how to instrument a site for remote data transmission
different technologies and different models of the same tech-
and no single reference on how to do this is available for
nology of turbidity meters can produce significantly different
reference here. The user is encouraged to visit the U.S.
outputs for the same environmental sample, only one manu-
Geological Survey’s Hydrologic Instrumentation Facility web-
facturer and model of the turbidity meter can be used to
site for information on equipment needs and used by the
develop the relationship between the SSC and turbidity read-
USGS.
ings at a site. If a different manufacturer or a different model
6.6 The installation of an automatic pumping sampler,
type of turbidity meter is used, a new relationship will need to
especially in remote areas, will allow samples to be collected
be develop for the site.
that can be used to relate the optical reading to the suspended-
sediment concentration in the stream and also address the
6. Apparatus
blackout periods discussed in 5.2. Detailed information con-
6.1 In general, three types of configurations of installations
cerning the installation and operation of pumping samplers is
of monitors can be used: (1) the flow-through monitoring
beyond the scope of this guide. See Edwards and Glysson (1)
system, (2) the in-situ monitoring system, and (3) the self
and Glysson (2) for more information on the use of automatic
contained, combined sensor and recording system.
pumping samplers.
6.2 Optical instruments such as photoelectric nephelometer
7. Site Selection
(best used for lower levels of SSC) and backscatter sensors
(best used for higher levels of SSC) provide the basis for this
7.1 The procedure for establishing a sampling location
method. For more information concerning the advantages and
should emphasize the quest for a stream-data site. A stream-
disadvantages of each, see Test Method D7315. As they
data site is as a cross section displaying relatively stable
become available, other sensors may be used.
hydrologic characteristics and uniform depths over a wide
3 4
The boldface numbers in parentheses refer to a list of references at the end of Available from http://www.act-us.info/evaluation.php.
this standard. Available from http://water.usgs.gov/hif.
D7512 − 09 (2015)
range of stream discharges, from which representative sedi- given stream conditions at one stage would produce the same
ment data can be obtained and related to a stage-discharge sampling point location relative to the flow conditions at a
rating and optical readings from the site. This is an idealized different stage. Therefore, generalized guidelines (modified
concept because the perfect site is rare at best. Therefore, it is from (1)) are outlined here and should be considered on a
necessary to note the limitations of the most suitable site case-by-case basis when selecting a sampling point.
available and build a program to minimize the disadvantages 8.1.1 Select a stable cross section of reasonably uniform
and maximize the advantages. depth and width to maximize the stability of the relationship
between sediment concentration at a point and the mean
7.2 Sites that may be affected by backwater conditions
sediment concentration in the cross section. This guideline is of
should be avoided whenever possible. Backwater condition is
primary importance in the decision to use an optical meter in a
a transient condition that occurs when water is backed up or
given situation; if a reasonably stable relation between the
retarded in a stream by tides or from inflow from another
sample-point reading and mean cross-section concentration
stream. Backwater affects both stage-discharge and velocity-
cannot be attained by the following outlined steps, the meter
discharge relationships. Therefore, a given discharge may have
should not be installed and an alternate location considered.
varying stage and mean stream velocity and thus have varying
8.1.2 Consider only the part of the vertical that could be
sediment transport rates.
sampled using a standard U.S. depth- or point-integrating
7.3 A sediment-measuring site located downstream from the
suspended-sediment sampler, excluding the unsampled zone,
confluence of two streams may require extra sediment mea-
because data collected with a depth- or point-integrating
surements due to incomplete mixing of the flows from the
sampler will be used to calibrate the optical meter. See Guide
tributaries. Moving the sampling location far enough down-
D4411 and Edwards and Glysson (1) for information on the
stream to ensure adequate mixing of the tributary flows should
unsampled zone, proper procedures, and equipment to collect
be investigated.
samples for SSC analysis.
7.4 Because sediment samples must be obtained more 8.1.3 Determine, if possible, the depth of the point of mean
frequently during high flows, and it is imperative that a site be sediment concentration in each vertical for each size class of
selected where obtaining data during these times are feasible. particles finer than 0.250 mm, from a series of carefully
Particular attention should be given to the ease of access to the collected point integrated samples. See Edwards and Glysson
(1) for information on the collection of point samples and Guy
water-stage recorder and to a usable bridge or cable during
high flows, many of which occur at night. Sites accessible only (5) for procedures for determining particle size of sediment
samples.
by poorly maintained backroads or trails should be avoided.
8.1.4 Determine, if possible, the mean depth of occurrence
7.5 The average monitoring site will consist of a shelter to
of the mean sediment concentration in each vertical for all
house and protect the equipment and some means for either
particles finer than 0.250 mm.
bringing water to the meters or conduits that will allow the
8.1.5 Use the mean depth of occurrence of the mean
meter to be placed in the flow zone of the channel. The shelter
sediment concentration in the cross section as a reference depth
should be located to minimize the distance between the stream
for placement of the sampling point.
and the meters, and at a high enough eleva
...
This document is not an ASTM standard and is intended only to provide the user of an ASTM standard an indication of what changes have been made to the previous version. Because
it may not be technically possible to adequately depict all changes accurately, ASTM recommends that users consult prior editions as appropriate. In all cases only the current version
of the standard as published by ASTM is to be considered the official document.
Designation: D7512 − 09 D7512 − 09 (Reapproved 2015)
Standard Guide for
Monitoring of Suspended-Sediment Concentration in Open
Channel Flow Using Optical Instrumentation
This standard is issued under the fixed designation D7512; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope
1.1 This guide covers the equipment and basic procedures for installation, operation, and calibration of optical equipment as a
surrogate for the continuous determination of suspended-sediment concentration (SSC) in open channel flow.
1.2 This guide emphasizes general principles for the application of optical measurements to be used to estimate suspended-
sediment concentration (SSC) in water. Only in a few instances are step-by-step instructions given. Continuous monitoring is a
field-based operation, methods and equipment are usually modified to suit local conditions. The modification process depends upon
the operator skill and judgment.
1.3 This guide covers the use of the output from an optical instrument, such as turbidity and suspended-solids meters, to record
data that can be correlated with suspended-sediment concentration. It does not cover the process of collecting data for continuous
turbidity record, which would require additional calibration of the turbidity readings to the mean turbidity of the measurement cross
section. For the purposes of this method it is assumed that the dependent variable will be mean cross-sectional suspended-sediment
concentration data.
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility
of the user of this standard to establish appropriate safety and health practices and to determine the applicability of regulatory
limitations prior to use.The values stated in SI units are to be regarded as standard. No other units of measurement are included
in this standard.
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility
of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory
limitations prior to use.
2. Referenced Documents
2.1 ASTM Standards:
D1129 Terminology Relating to Water
D3977 Test Methods for Determining Sediment Concentration in Water Samples
D4410 Terminology for Fluvial Sediment
D4411 Guide for Sampling Fluvial Sediment in Motion
D6764 Guide for Collection of Water Temperature, Dissolved-Oxygen Concentrations, Specific Electrical Conductance, and pH
Data from Open Channels
D7315 Test Method for Determination of Turbidity Above 1 Turbidity Unit (TU) in Static Mode
3. Terminology
3.1 Definitions:
3.1.1 calibration drift, n—the error that is the result of drift in the sensor reading from the last time the sensor was calibrated,
and is determined by the difference between cleaned-sensor readings in calibration standards and the true, temperature-
compensated value of the calibration standards.
This practice is under the jurisdiction of ASTM Committee D19 on Water and is the direct responsibility of Subcommittee D19.07 on Sediments, Geomorphology, and
Open-Channel Flow.
Current edition approved Oct. 1, 2009Jan. 15, 2015. Published October 2009February 2015. Originally approved in 2009. Last previous edition approved in 2009 as D7512
– 09. DOI: 10.1520/D7512-09.10.1520/D7512-09R15.
For referenced ASTM standards, visit the ASTM website, www.astm.org, or contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM Standards
volume information, refer to the standard’s Document Summary page on the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
D7512 − 09 (2015)
3.1.2 fouling, n—the error that can result from a variety of sources (such as biological growth on the sonde and covering of the
probe with sediment), and is determined by the difference between sensor measurements in the environment before and after the
sensors are cleaned.
3.1.2 continuous, adj—refers to a time series of unit values that are close enough in time to simulate a continuous record.
3.1.2.1 Discussion—
Generally, in studies of open-channel flow, 15-minute intervals are used and are adequate to estimated continuous record. However,
the time interval maybe as little as a minute or as great as an hour.
3.1.3 fouling, n—the error that can result from a variety of sources (such as biological growth on the sonde and covering of the
probe with sediment), and is determined by the difference between sensor measurements in the environment before and after the
sensors are cleaned.
3.1.4 sonde, n—part of the monitoring equipment that contains the measurement sensors.
3.1.4.1 Discussion—
A sonde may be either a single parameter sensor or a combination of different sensors of different parameters.
4. Summary of Guide
4.1 This guide covers the equipment and basic procedures for installation, operation, and calibration of optical equipment as a
surrogate for the continuous or near continuous determination of SSC in open channel flow.
4.2 This guide emphasizes general principles for one particular application of optical measurements in water. This guide covers
the use of nephelometers and backscatter type turbidity meters to record data that can be correlated with SSC.
5. Significance and Use
5.1 This guide is general and intended as a planning guide. To satisfactorily monitor a specific site, an investigator must
sometimes design specific installation structures or modify those given in this guide to meet the requirements of the site in question.
Because of the dynamic nature of the sediment transport process, the extent to which characteristics such as mass concentration
and particle-size distribution are accurately represented in the monitoring program depends on the type of equipment used and
method of collection of the SSC samples used to calibrate the optical readings. Sediment concentration is highly variable in both
time and space. Numerous samples must be collected and analyzed with proper equipment and standardized methods for the rating
of the optical equipment at a particular site (see Guide D4411 and Practice D3977).
5.2 All optical equipment have an upper limit for valid readings, beyond which the meter will not read properly, commonly
referred to as “blacking out.” If upper range of SSC are expected to cause optical instrument black out, then some other means
should be devised, such as automatic pumping samplers, to collect samples during this period. See Edwards and Glysson (1) and
Glysson (2) for information on collection of suspended sediment samples using pumping samplers. It should be noted that other
technologies, such as lasers and acoustic dopplers, are also being used to monitor SSC continuously.
5.3 The user of this guide should realize that because different technologies and different models of the same technology of
turbidity meters can produce significantly different outputs for the same environmental sample, only one manufacturer and model
of the turbidity meter can be used to develop the relationship between the SSC and turbidity readings at a site. If a different
manufacturer or a different model type of turbidity meter is used, a new relationship will need to be develop for the site.
6. Apparatus
6.1 In general, three types of configurations of installations of monitors can be used: (1) the flow-through monitoring system,
(2) the in-situ monitoring system, and (3) the self contained, combined sensor and recording system.
6.2 Optical instruments such as photoelectric nephelometer (best used for lower levels of SSC) and backscatter sensors (best
used for higher levels of SSC) provide the basis for this method. For more information concerning the advantages and
disadvantages of each, see Test Method D7315. As they become available, other sensors may be used.
6.2.1 The Alliance for Coastal Techniologies (ACT) did an in-situ evaluation of different nephelometer technologist. Users of
this Guideguide may be interested in the results of this study which can be form on found online.the web at http://www.act-
us.info/evaluation_reports.php.
The boldface numbers in parentheses refer to a list of references at the end of this standard.
Available from http://www.act-us.info/evaluation.php.
D7512 − 09 (2015)
6.3 Before selecting the type of meter to be used, the operator needs to review the site requirements in order to ensure selection
of the proper instrumentation. Things to consider, but are not limited to, are: the instruments ability to survive the study site
environment, the degree of fouling that may take place, and the range of readings likely to be encountered at the site.
6.4 If a flow-through or in-situ monitoring device is used, a recording system must be installed. The recording system must have
enough storage capacity to store all data recorded between site service visits. See manufacturer’s advice on which recording
devices will work best for the type of monitor being used.
6.5 Remote access and near real-time transmission of data from the site to the office can be very important in meeting the
objectives of the monitoring station. Remote access and the near real-time transmittal of the recorded data take other equipment
(such as a data collection platform (DCP), and transmittal antenna) in addition to the optical sensor. A DCP performs the same
fundamental function as a basic data recorder (BDR). They both collect data from attached sensors on a timed interval and store
the results. The difference is the BDR retains the data until it is retrieved manually, while the DCP has the ability to transmit the
collected data to another location. Since data is transferred elsewhere for storage shortly after collection, a DCP may have less
memory than a BDR. The data may be transmitted via telephone modem, line-of-site radio link or satellite. It is beyond the scope
of this guide to discuss how to instrument a site for remote data transmission and no single reference on how to do this is available
for reference here. The user is encouraged to visit the U.S. Geological Survey’s Hydrologic Instrumentation Facility webwebsite
site for information on equipment needs and used by the USGS (http://wwwhif.er.usgs.gov/public/contacts.htm).USGS.
6.6 The installation of an automatic pumping sampler, especially in remote areas, will allow samples to be collected that can
be used to relate the optical reading to the suspended-sediment concentration in the stream and also address the blackout periods
discussed in Section 5.2. Detailed information concerning the installation and operation of pumping samplers is beyond the scope
of this guide. See Edwards and Glysson (1) and Glysson (2) for more information on the use of automatic pumping samplers.
7. Site Selection
7.1 The procedure for establishing a sampling location should emphasize the quest for a stream-data site. A stream-data site is
as a cross section displaying relatively stable hydrologic characteristics and uniform depths over a wide range of stream discharges,
from which representative sediment data can be obtained and related to a stage-discharge rating and optical readings from the site.
This is an idealized concept because the perfect site is rare at best. Therefore, it is necessary to note the limitations of the most
suitable site available and build a program to minimize the disadvantages and maximize the advantages.
7.2 Sites that may be affected by backwater conditions should be avoided whenever possible. Backwater condition is a transient
condition that occurs when water is backed up or retarded in a stream by tides or from inflow from another stream. Backwater
affects both stage-discharge and velocity-discharge relationships. Therefore, a given discharge may have varying stage and mean
stream velocity and thus have varying sediment transport rates.
7.3 A sediment-measuring site located downstream from the confluence of two streams may require extra sediment
measurements due to incomplete mixing of the flows from the tributaries. Moving the sampling location far enough downstream
to ensure adequate mixing of the tributary flows should be investigated.
7.4 Because sediment samples must be obtained more frequently during high flows, and it is imperative that a site be selected
where obtaining data during these times are feasible. Particular attention should be given to the ease of access to the water-stage
recorder and to a usable bridge or cable during high flows, many of which occur at night. Sites accessible only by poorly
maintained backroads or trails should be avoided.
7.5 The average monitoring site will consist of a shelter to house and protect the equipment and some means for either bringing
water to the meters or conduits that will allow the meter to be placed in the flow zone of the channel. The shelter should be located
to minimize the distance between the stream and the meters, and at a high enough elevation to protect the equipment during
flooding events. Some instruments may need AC power and therefore the proximity to power lines is important.
7.6 For additional information and discussion on the selection of a site for the collection of surface water and sediment data see
Edwards and Glysson (1), Wagner and otherset al. (3), and Rantz and others et al.(4).
8. Installation of Equipment
8.1 Placement of sensor in cross section of the stream: The primary consider when placing an optical meter, sensor, or water
intake (collectively referred in this section as “sampling point.”) in the streamflow at a cross section is that only one point in the
flow is being sampled. Therefore, to yield reliable and representative data, the sampling point should be placed at the point where
the concentration approximates the mean SSC for the cross section for the full range of flows. SSC data may have to be collected
from several verticals in the cross section to help define where the mean SSC values is most likely to accrue (see (1)). This is an
idealistic concept and the mean cross-section concentration almost never exists at the same point under varying stre
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