NZ729151B2 - Measurement and treatment of fluid streams - Google Patents
Measurement and treatment of fluid streams Download PDFInfo
- Publication number
- NZ729151B2 NZ729151B2 NZ729151A NZ72915115A NZ729151B2 NZ 729151 B2 NZ729151 B2 NZ 729151B2 NZ 729151 A NZ729151 A NZ 729151A NZ 72915115 A NZ72915115 A NZ 72915115A NZ 729151 B2 NZ729151 B2 NZ 729151B2
- Authority
- NZ
- New Zealand
- Prior art keywords
- particles
- fluid stream
- sample
- aliquot
- stream
- Prior art date
Links
- 239000012530 fluid Substances 0.000 title claims abstract description 107
- 238000005259 measurement Methods 0.000 title claims description 10
- 239000002245 particle Substances 0.000 claims abstract description 137
- 238000000034 method Methods 0.000 claims abstract description 59
- 239000000126 substance Substances 0.000 claims description 20
- 238000012545 processing Methods 0.000 claims description 15
- 238000011144 upstream manufacturing Methods 0.000 claims description 13
- 239000000701 coagulant Substances 0.000 description 53
- 239000000706 filtrate Substances 0.000 description 50
- 239000002002 slurry Substances 0.000 description 46
- 239000002562 thickening agent Substances 0.000 description 36
- 239000002351 wastewater Substances 0.000 description 33
- 238000005189 flocculation Methods 0.000 description 28
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- 239000004927 clay Substances 0.000 description 11
- 125000002091 cationic group Chemical group 0.000 description 10
- 239000010419 fine particle Substances 0.000 description 10
- 238000005065 mining Methods 0.000 description 10
- 238000001914 filtration Methods 0.000 description 9
- 229920002401 polyacrylamide Polymers 0.000 description 8
- 239000010865 sewage Substances 0.000 description 8
- 239000010802 sludge Substances 0.000 description 8
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 8
- 238000004140 cleaning Methods 0.000 description 6
- 238000004519 manufacturing process Methods 0.000 description 6
- 230000007246 mechanism Effects 0.000 description 6
- 230000008569 process Effects 0.000 description 6
- 230000009467 reduction Effects 0.000 description 6
- 239000003250 coal slurry Substances 0.000 description 5
- 235000013365 dairy product Nutrition 0.000 description 5
- 235000013305 food Nutrition 0.000 description 5
- 239000000084 colloidal system Substances 0.000 description 4
- 239000007788 liquid Substances 0.000 description 4
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- 230000014759 maintenance of location Effects 0.000 description 4
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- 238000005070 sampling Methods 0.000 description 4
- 239000010801 sewage sludge Substances 0.000 description 4
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- 150000004649 carbonic acid derivatives Chemical class 0.000 description 1
- 238000006243 chemical reaction Methods 0.000 description 1
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Classifications
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/52—Treatment of water, waste water, or sewage by flocculation or precipitation of suspended impurities
- C02F1/5209—Regulation methods for flocculation or precipitation
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/52—Treatment of water, waste water, or sewage by flocculation or precipitation of suspended impurities
- C02F1/54—Treatment of water, waste water, or sewage by flocculation or precipitation of suspended impurities using organic material
- C02F1/56—Macromolecular compounds
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2103/00—Nature of the water, waste water, sewage or sludge to be treated
- C02F2103/10—Nature of the water, waste water, sewage or sludge to be treated from quarries or from mining activities
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2209/00—Controlling or monitoring parameters in water treatment
- C02F2209/005—Processes using a programmable logic controller [PLC]
- C02F2209/008—Processes using a programmable logic controller [PLC] comprising telecommunication features, e.g. modems or antennas
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2209/00—Controlling or monitoring parameters in water treatment
- C02F2209/05—Conductivity or salinity
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2209/00—Controlling or monitoring parameters in water treatment
- C02F2209/10—Solids, e.g. total solids [TS], total suspended solids [TSS] or volatile solids [VS]
- C02F2209/105—Particle number, particle size or particle characterisation
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2209/00—Controlling or monitoring parameters in water treatment
- C02F2209/11—Turbidity
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N1/00—Sampling; Preparing specimens for investigation
- G01N1/02—Devices for withdrawing samples
- G01N1/10—Devices for withdrawing samples in the liquid or fluent state
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N1/00—Sampling; Preparing specimens for investigation
- G01N1/02—Devices for withdrawing samples
- G01N1/10—Devices for withdrawing samples in the liquid or fluent state
- G01N2001/1006—Dispersed solids
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N1/00—Sampling; Preparing specimens for investigation
- G01N1/02—Devices for withdrawing samples
- G01N1/10—Devices for withdrawing samples in the liquid or fluent state
- G01N2001/1006—Dispersed solids
- G01N2001/1012—Suspensions
- G01N2001/1025—Liquid suspensions; Slurries; Mud; Sludge
Abstract
method and system for measuring and treating fluid streams having particles therein is disclosed. A sample of the fluid stream is obtained and processed to remove large particles, to obtain an aliquot of the fluid stream with some particles therein. A parameter in the aliquot is measured that relates to quantity and/or charge of the particles. The aliquot was found to be representative of the whole fluid stream, so when the parameter deviates from a desired value, this indicates that particles in the fluid stream require treatment. The method and system can further include treating the particles in the fluid stream until the measured parameter in the aliquot returns to the desired value. tes to quantity and/or charge of the particles. The aliquot was found to be representative of the whole fluid stream, so when the parameter deviates from a desired value, this indicates that particles in the fluid stream require treatment. The method and system can further include treating the particles in the fluid stream until the measured parameter in the aliquot returns to the desired value.
Description
MEASUREMENT AND TREATMENT OF FLUID STREAMS
TECHNICAL FIELD
A method and system for measuring and treating fluid streams is disclosed.
The method and system find particular application with treating aqueous suspensions
and dispersions, such as, water and wastewater streams in mining and mineral
processing, sewage treatment, power generation, pulp and papermaking, sludge
dewatering, food and dairy manufacturing, and industrial liquid waste applications, but
are not limited to these applications.
BACKGROUND ART
Water and wastewater streams in mining and mineral processing, sewage
treatment, power generation, pulp and papermaking, sludge dewatering, food and dairy
manufacturing, and industrial liquid waste can have particulate matter suspended
therein, the amount and contents of which can vary. Such variations can have
implications for downstream processing of the wastewater, and may result in
downstream processes having to be temporarily shut down, with resultant time and
cost consequences.
US 5,846,433 discloses a process for flocculating a sewage sludge to form a
thickened sludge/cake and a separated liquor. The process monitors a dewatering
parameter of the liquor, which monitoring can be used to pre-treat the sewage sludge
prior to dewatering.
A reference herein to the prior art does not constitute an admission that the art
forms part of the common knowledge of a person of skill in the art, and is not intended
to limit the scope of the method and system disclosed herein.
SUMMARY OF THE DISCLOSURE
Disclosed herein is a method for treating a fluid stream that comprises particles.
The fluid stream may comprise a mixture of particles (i.e. particles of varying size and
properties may be present in the fluid stream). The fluid stream may be a liquid
stream, and may be an aqueous or non-aqueous stream. The fluid stream may also
include product streams and/or waste streams (e.g. wastewater). The fluid stream
may include particles whose presence is undesirable insofar as treatment of the fluid
stream is concerned. For example, a mining wastewater stream may comprise
suspended tailings or solids that require treatment, but may additionally comprise
18185438_1 (GHMatters) P97118.NZ 23/10/21
undesirable (e.g. fine particles such as colloidal and sub-colloidal clay) particles. The
method as disclosed herein can, in this example, indicate that a treatment of the
undesirable particles (i.e. the clay particles) is required, whereby a treatment regime
(i.e. existing wastewater treatment) for the suspended tailings or solids need not be
affected or interfered with. In another example, the fluid stream may be the product
line in a pulp or papermaking process (e.g. pulp slurry). In such an example, it may be
preferred to increase the retention of fine and ultrafine particles (e.g. wood fiber, clay,
fillers, etc.) in the pulp slurry to increase paper yield. The method as disclosed herein
can, in this example, indicate that an adjustment in the treatment of the particles (e.g.
the wood fiber particles) is required (e.g. adjustment of coagulant dosing, such as
alum, is required to maintain optimal retention of paper fines).
The method may be deployed in the treatment of fluid streams, including
aqueous suspensions and dispersions such as are produced in mining and mineral
processing, sewage treatment, power generation, pulp and papermaking, sludge
dewatering, food and dairy manufacturing, and industrial liquid waste applications, but
is not limited to these applications.
The method comprises obtaining a sample that is an offtake of a main or major
flow of the fluid stream, the sample offtake containing the particles of varying size
present in the fluid stream. The sample may be obtained at one, or at various stages
or locations of a fluid treatment regime (e.g. from a feed or tailings pipe, treatment (e.g.
settling or thickening) vessel, filtration stage, holding vessel or settling pond, etc.).
The sample may be obtained continuously, for example, as a continuous side
stream offtake or a continuous bleed stream offtake of the fluid stream at one of the
various stages or locations of the fluid treatment regime.
The method also comprises processing the sample offtake to remove particles
therefrom that are above a certain size, the processing obtaining an aliquot that
contains particles from the fluid stream that have a size less than the certain size (e.g.
the undesirable fine particles such as colloidal and sub-colloidal clay in a mining
wastewater stream, or desirable fine particles such as colloidal and sub-colloidal wood
fibers in a papermaking pulp slurry) when they are present in the fluid stream.
Processing of the sample offtake may include filtering, centrifuging, hydrocycloning or
another process to remove large particles therefrom. For example, the sample offtake
may be filtered using e.g. a cross-flow filter, which is self-cleaning, to obtain the aliquot
(in the form of a filtrate). The sample offtake may alternatively or additionally be
filtered through a microporous membrane under vacuum with periodic backflush
18185438_1 (GHMatters) P97118.NZ 23/10/21
cleaning. In another example, the sample may be spun in a hydrocyclone or a
centrifuge to obtain the aliquot (in the form of a centrate) containing the desired particle
distribution. Other self-cleaning apparatus may be employed. Such apparatus can
help to maintain continuity of the method in use. The filtering or centrifuging can be
employed to remove from the sample particles which can otherwise interfere with a
measuring step (e.g. to remove larger particles that are suspended in a wastewater
stream, such as the mineral tailings, mineral residues, sewage sludge, etc.).
In some forms, obtaining and processing the sample offtake to obtain the
aliquot may occur concurrently. In other forms, obtaining the sample offtake and
processing of the sample offtake to obtain the aliquot may occur separately.
Also, depending on the fluid stream, the particles may comprise other
colloidal/sub-colloidal particles, or other fine (e.g. insoluble) particles that are
suspended or (e.g. microscopically) dispersed in the stream, and whose presence can
interfere with the treatment regime for the particular fluid stream.
The method further comprises measuring in the aliquot one or more parameters
that relate to quantity and/or charge of the particles in the aliquot such that, when the
one or more parameters deviate from a desired value, this indicates that the particles
in the fluid stream require treatment. A continuous flow of the aliquot may be
measured.
The method further comprises selecting a chemical that is suitable for treating
the particles in the fluid stream that require treatment and adding the chemical to the
fluid stream.
In accordance with the method as disclosed herein, when the parameter
deviates from a desired value, this can indicate that the (e.g. undesirable) particles in
the fluid stream require treatment. In other words, it has been discovered that a
sample offtake (e.g. side or bleed stream) aliquot can be used to indicate that a main
or major flow of fluid requires treatment. Further, such an indication may be
preemptive, as may be the treatment, in that, as soon as a deviation is detected,
corrective action can be implemented (e.g. immediately and automatically) to treat the
main/major flow of fluid.
The method can further comprise continuing the treatment until the measured
parameter(s) in the aliquot return(s) to the desired value. In this regard, the aliquot is
obtained from a sample of the treated fluid stream (i.e. the subsequently measured
sample and aliquot is obtained downstream of where treatment of the fluid stream has
taken place). Alternatively, and as outlined above, the sample offtake (and hence
18185438_1 (GHMatters) P97118.NZ 23/10/21
aliquot) may be obtained continuously and will thus be representative of the treated
fluid stream, when the fluid stream is treated at a location upstream of where the
sample offtake and aliquot is obtained.
It should be understood that the measured value of the parameter will depend
on the type of measurement and type of meter employed. For example, each of a
streaming current detector (meter), colourimeter, conductivity meter, turbidity meter,
etc. will measure a different parameter/value. Thus, the desired value will vary with the
type of measurement and type of meter.
Further, the term “desired” in relation to the value is intended to indicate that
the value as measured is suitable to the particular treatment regime for the fluid (e.g.
that an indicated level of the particle will not interfere with the treatment regime for the
fluid). It should be further understood that this value will also vary with the fluid
application (e.g. tailings, mineral processing, sewage, food and dairy manufacturing,
etc.), as well as with the site, as well as with the type of solid materials suspended in
the fluid.
In one embodiment the desired value of the parameter(s) may comprise a set
(value) point, or it may comprise a set range of values. As above, the set point or set
range can be determined with reference to the fluid stream so as to be suitable for its
particular treatment regime. The set point or set range may be programmed into a
controller.
Further, in one embodiment, the parameter(s) may be selected that are known
to deviate from the desired value when particle(s) are present in the fluid stream are
such as to render the stream unsuitable for the treatment regime.
In one embodiment, usually the treatment regime comprises treating other
particulate matter in the fluid stream (e.g. to capture mineral tailings, mineral residues,
sewage sludge, etc. and separate it from the water). In the method disclosed herein,
this other particulate matter is typically removed (e.g. filtered, centrifuged or separated
as a fraction in a hydrocyclone) from the sample offtake before measurement.
It has been discovered that the (e.g. undesirable) particles that are measured in
the sample aliquot can correspond to those that are present in the fluid stream,
whereby the parameter measured in the aliquot (including any deviations from a
desired value) can be representative or indicative of the particles (and deviations) in
the fluid stream. This stands in contradistinction to US 5,846,433, where the entire
liquor separated from the sewage filter cake is measured. In other words, in the
method as disclosed herein, a side or bleed stream of the fluid stream may be
18185438_1 (GHMatters) P97118.NZ 23/10/21
sampled, processed (such as by filtering or centrifuging) to obtain an aliquot containing
particles of a certain size, and this aliquot used to measure and detect deviations in the
parameter (and hence measure changes in the quantity and/or charge of particles
present in the fluid stream).
So, for example, as soon as such deviations are detected, an appropriate (e.g.
corrective) treatment of the fluid stream can be implemented. This may take the form
of selecting and dispensing a suitable chemical (e.g. a coagulant, flocculant, clarifying
or precipitation agent, acid, base, salt, etc.) into the fluid stream. As mentioned above,
this dispensing can be preemptive, and can ensure that the treatment regime for the
fluid stream is not shut down or taken “offline”. The dispensing may also be
proportional (e.g. it may be controlled) to the level of desirable or undesirable particles
in the fluid stream.
For example, the amount of chemical dispensed can be sufficient to coagulate,
flocculate or agglomerate undesirable particles such that they then do not interfere with
the fluid stream treatment regime, and rather may be removed as part of the normal
fluid stream treatment regime. Similarly, the amount of chemical dispensed can be
sufficient to coagulate, flocculate or agglomerate desirable particles such that their
capture and retention is optimized for subsequent treatment regimes.
In one embodiment the chemical may be automatically dispensed into the fluid
stream. For example, the automatic dispensing can form part of a controlled feedback
loop, in which a parameter value deviation is measured, a signal is sent to an
automatic dispenser, which continues to dispense until the measured value returns to a
set point or within a set range.
When the particles to be treated and the particles that are measured in the
aliquot comprise colloidal and/or sub-colloidal e.g. clay particles, the suitable chemical
may comprise a suitable coagulant. The coagulant can cause the colloidal and/or sub-
colloidal clay particles to coagulate, to then enable them to be separated from the fluid
stream as part of the treatment regime (whether that treatment regime be to collect the
coagulated particles or the fluid separated therefrom).
In another embodiment, the suitable chemical may comprise a flocculant,
clarifying agent or precipitation agent that causes the particles to flocculate, settle out,
agglomerate, precipitate and/or become filterable or separable.
In one embodiment, the parameter of the particles which relates to the charge
of the particles may be the net surface charge of the particles. The net surface charge
of the particles may be determined by measuring charge demand using a streaming
18185438_1 (GHMatters) P97118.NZ 23/10/21
current detector or colourimeter. When measuring using the streaming current
detector, a coagulant can be dosed into the aliquot. When measuring using a
colourimeter, an indicator dye can be dosed into the aliquot.
Alternatively, or additionally, the parameter relating to charge may be the
conductivity of the particles, which may be measured using a conductivity meter.
In one embodiment, the parameter of the particles that relates to the quantity of
the particles may be the turbidity of the aliquot. The turbidity of the aliquot may be
measured using a turbidity meter. Thus, a deviation in the turbidity reading of the
aliquot (e.g. from a set point, or outside of a set range) can indicate that corrective
action (e.g. dispensing of a corrective chemical into the fluid stream) is required.
In one embodiment, the sample offtake may be processed such that the aliquot
contains a maximum particle size of less than about 20 micrometres, typically less than
about 10 micrometres, and more typically less than about 5 micrometres.
In one embodiment, the method may further comprise continuously recording
and outputting characteristics of the fluid stream that relate to the measured
parameter. For example, these characteristics may be uploaded to a server for remote
viewing and monitoring (e.g. via the internet, or a proprietary intranet, etc.).
Also disclosed herein is a method for treating a fluid stream that comprises
particles of varying size suspended in the fluid stream, the method comprising:
- obtaining a sample of a main or major flow of the fluid stream, the sample
containing the suspended particles of varying size in the fluid stream;
- processing the sample to remove from the sample particles of the suspended
particles of the varying size that are above a certain size, to obtain an aliquot that
contains suspended particles from the fluid stream that have a maximum particle size
of less than 20 micrometres;
- measuring in the aliquot one or more parameters that relate to quantity and/or
charge of the suspended particles from the fluid stream that have a size of less than 20
micrometres such that, when the one or more parameters deviate from a desired
value, this indicates that the suspended particles of the varying size in the fluid stream
require treatment;
- using measurements of the one or more parameters to determine whether the
suspended particles of the varying size in the fluid stream require treatment;
- selecting a chemical that is suitable for treating the suspended particles of the
varying size in the fluid stream that require treatment; and
- adding the chemical to the fluid stream.
18185438_1 (GHMatters) P97118.NZ 23/10/21
Also disclosed herein is a system for treating a fluid stream that comprises
particles of varying size present in the fluid stream.
The system comprises an apparatus for obtaining a sample of the fluid stream
that is an offtake of a main or major flow of the fluid stream, such that the sample
offtake contains the particles of varying size present in the fluid stream. The system
also comprises an apparatus for processing the sample offtake to remove particles
therefrom that are above a certain size, the apparatus producing an aliquot that
contains particles from the fluid stream that have a size less than the certain size. The
system further comprises a meter for measuring in the aliquot one or more
parameter(s) that relate to quantity and/or charge of the particles in the aliquot. The
meter is further able to measure when the parameter(s) deviate from a desired value to
indicate that the particles in the fluid stream require treatment. The system further
comprises a dispensing mechanism for dispensing into the fluid stream a chemical that
is suitable for treating the particles in the fluid stream that require treatment.
In one embodiment, the system may further comprise a processor for receiving
a signal from the meter and sending that signal to the dispensing mechanism to
dispense the chemical into the fluid stream.
Also disclosed herein is a system for treating a fluid stream that comprises
particles of varying size present in the fluid stream, the system comprising:
- an apparatus for obtaining a sample of the fluid stream of a main or
major flow of the fluid stream, such that the sample contains the suspended particles of
varying size present in the fluid stream;
- an apparatus for processing the sample to remove from the sample
particles of the suspended particles of the varying size that are above a certain size, to
obtain an aliquot that contains suspended particles from the fluid stream that have a
size of less than 20 micrometres;
- a meter for measuring in the aliquot one or more parameters that relate
to quantity and/or charge of the suspended particles from the fluid stream that have a
size less than a certain size, the meter able to measure when the parameter(s) deviate
(s) from a desired value to indicate that the suspended particles of the varying size in
the fluid stream require treatment;
- a processor for receiving a signal from the meter and dispensing a
chemical that is suitable for treating the corresponding particles into the fluid stream;
18185438_1 (GHMatters) P97118.NZ 23/10/21
- a dispensing mechanism for receiving a signal from the processor and
for adding the chemical to the fluid stream to enable the corresponding particles to be
separated from the stream.
Components of the system may be otherwise as set forth above.
BRIEF DESCRIPTION OF THE DRAWINGS
Notwithstanding any other forms which may within the method and system as
set forth in the Summary, specific embodiments of the method and system will now be
described, by way of example only, with reference to the accompany drawings in
which:
Figure 1 shows a schematic flow sheet for a method and system for measuring
a surface charge of particles using a streaming current detector or colourimeter, and
for dosing a wastewater stream; and
Figure 2 shows a schematic flow sheet for a method and system for measuring
a quantity of particles using a turbidity meter, and for dosing a wastewater stream.
DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS
Figure 1 shows a schematic flow sheet for a method and a system 10 for
measuring a surface charge of particles using a streaming current detector or
colourimeter. Figure 1 also schematically indicates an upstream coagulant dosing 12
of a wastewater stream. Figure 2 shows a schematic flow sheet for a method and a
system 100 for measuring a quantity of particles using a turbidity meter. Figure 2 also
schematically indicates an upstream coagulant dosing 102 of a wastewater stream.
Referring firstly to Figure 1, the system 10 is used to measure and treat a
wastewater stream comprising suspended solids. The suspended solids include
colloidal and/or sub-colloidal particles entrained therein. Such wastewaters are typical
in the mining, minerals processing and sewage treatment industries.
The system 10 is configured to continuously obtain a sample from the
wastewater stream and to filter the sample continuously, as well as to continuously
measure and treat the wastewater, as described hereafter.
The system 10 comprises an apparatus for obtaining a sample stream of the
wastewater stream in the form of an offtake pipe 14, which receives a side or bleed
stream from a slurry feed pipe (or thickener feedwell) 16. The slurry feed pipe or
thickener feedwell form part of a standard treatment regime for the wastewater. The
18185438_1 (GHMatters) P97118.NZ 23/10/21
sample offtake is caused by a pump 20 to pass through a pressure control valve 18, a
further control valve 22, and via a PI controller 24 to a filter.
The filter takes the form of a crossflow filter 26 which is arranged to
continuously filter the sample to obtain a filtrate. Such a crossflow filter is self-
cleaning, but can be periodically cleaned by an air backflow system 27.
The filtrate passes laterally from the crossflow filter 26 into a filtrate pipe 28,
and then via a PI controller 30 to a filtrate reservoir 32. The filtrate comprises a
fraction of the suspended particles that formed a part of the suspended solids in the
wastewater stream.
The remaining filter residue passes through the crossflow filter 26 as slurry 34,
via a further PI controller 36 and pressure control valve 38 and into a flow meter (flow
element) 40. From here, the slurry is returned to the slurry feed pipe (or thickener
feedwell) 16.
The crossflow filter 26 can comprise a porous, sintered metal tubular filter that
filters the sample stream such that the filtrate contains particles with a maximum size in
the range of about 1 to 5 micrometres. Such a particle size range can ensure that
colloidal and/or sub-colloidal particles pass into the filtrate, whereas other larger
particles (e.g. minerals residues, sludge, etc.) in the sample stream pass through the
filter as slurry 34, and are returned to the slurry feed pipe (or thickener feedwell) 16.
Depending on the nature of the particles, other self-cleaning apparatus for filtration or
centrifugation may be employed such as vacuum or brushed screen filters,
hydrocyclones, etc.
The filtrate from the filtrate reservoir 32 is fed via a normally open valve 42 and
further pressure control valve 44 to a static mixer 46. An opposing normally closed
valve 47 forms part of the air backflow system 27 (i.e. when air from 27 is used to flush
clean the filter, the valve 42 can be closed and the valve 47 opened). Instead of or
additional to the air backflow system 27, ultrasonic cleaning can be employed.
A titrant 48 from a titrant holding tank 50 is caused by a pump 52 to be dosed
into the filtrate before it passes into the static mixer 46. When measuring the filtrate
using a streaming current detector 54, a titrant in the form of a dilute coagulant is
dosed into the filtrate to enable charge neutralisation of the colloidal and/or sub-
colloidal particles, resulting in a detectable change in streaming current value. When
measuring the filtrate using a colourimeter 54, a titrant in the form of an
indicator/coagulant dye is dosed into the filtrate, which agglomerates with the colloidal
and/or sub-colloidal particles, resulting in a change of colour. In either case, the titrant
18185438_1 (GHMatters) P97118.NZ 23/10/21
and filtrate are mixed together in the static mixer 46, and allowed to react in a reaction
vessel 56, before being passed to the streaming current detector or colourimeter 54.
Each of the streaming current detector or colourimeter 54 measures in the
filtrate a parameter that relates to charge of the particles in the filtrate. More
specifically, the parameter of the particles which is measured is the net surface charge
of the particles. Further, the net surface charge of the particles is determined by
measuring the cationic charge demand using the streaming current detector or
colourimeter 54. The measured filtrate is returned as stream 55 to the slurry feed pipe
(or thickener feedwell) 16.
A controller 60 is arranged to receive the signal 62 output by the detector or
meter 54. The controller 60 is programmed to detect when the measured parameter
deviates from a particular, desired value. This deviation indicates that corresponding
particles in the wastewater stream require some form of treatment, as described
hereafter.
The controller 60 is in turn arranged to output a signal 64 to dispensing
mechanism in the form of a coagulant dosing pump 66 that doses a suitable coagulant
into the wastewater stream, upstream from the sample offtake pipe 14, as described
hereafter. A coagulant dosing mechanism is used when the particles that have passed
into the filtrate are in excess of the set point or set range.
The controller 60 can take the form of a programmable processor (e.g. micro-
processor) that can be pre-programmed to memorise a particular, desired value of the
measured parameter. For example, in the case where the meter is a streaming current
detector, the measured parameter may be a set range of current or voltage values, or
e.g. a set point of around 0. Deviations from this range or point are measured,
detected, and then a signal 64 is sent to the coagulant dosing pump 66 to dose a
coagulant into the wastewater stream. This dosing enables the colloidal/sub-colloidal
particles to be removed (e.g. filtered/settled) and continues until the measured
parameter in the filtrate returns to the set range or set point.
In the case where the meter is a colourimeter, the measured parameter may be
a set range (spectrum) of wave length absorption.
For some wastewaters, the meter 54 may take the form of a conductivity meter,
for example, where the filtrate has a low salt level, and therefore conductivity can be
indicative of particle (e.g. colloidal/sub-colloidal) surface charge.
The controller (processor) 60 can also be configured to continuously record and
output characteristics of the wastewater stream that relate to the particular parameter
18185438_1 (GHMatters) P97118.NZ 23/10/21
being measured. These characteristics can be uploaded to a server for remote
viewing and monitoring via the internet, or a proprietary intranet, etc.
Referring now to Figure 2, the system 100 is again used to measure and treat a
wastewater stream comprising suspended solids including colloidal and/or sub-
colloidal particles entrained therein. In Figure 2, like reference numbers to Figure 1 are
employed for like parts, but with 100 added thereto. Where the system comprises
components that are generally the same as in Figure 1 they will not be re-described,
for the sake of brevity.
The system 100 is again configured to continuously obtain a sample from the
wastewater stream and to filter the sample continuously, as well as to continuously
measure and treat the wastewater.
In system 100, however, the parameter to be measured relates to quantity.
Hence, the meter takes the form of a turbidimeter 154 for measuring turbidity of the
filtrate stream 155. Because particle charge is no longer being measured, the titrant
48 and associated titrant dosing, mixing and reacting can be eliminated. Hence, the
system 100 is simpler than the system 10.
In the case of a turbidity meter, the measured parameter may be a set range of
NTU values (e.g. 0-5 NTU) or a set point (e.g. ~ 2 NTU), indicating that a sufficiently
low amount of colloidal/sub-colloidal particles are present in the wastewater. When the
turbidity meter measures above this range or set point, the controller 160 detects when
this deviation from the desired value occurs. The controller 160 then outputs a signal
164 to the coagulant dosing pump 166, which in turn doses a suitable coagulant into
the wastewater stream, upstream from the sample offtake pipe 14.
Whilst Figures 1 and 2 refer to schematic flow sheets for the treatment of
wastewater streams, it should be appreciated that the method and system disclosed
therein could be deployed in the treatment of other fluid streams, such as where the
fluid stream is a product stream (as opposed to a waste stream). In this regard, the
method and system exemplified in Figures 1 and 2 could be deployed in the treatment
of various fluid streams, including aqueous suspensions and dispersions such as are
produced in mining and mineral processing, sewage treatment, power generation, pulp
and papermaking, sludge dewatering, food and dairy manufacturing, and industrial
liquid waste applications, but it will be appreciated that the method and system
exemplified in the Figures is not so limited. It will also be appreciated that the method
and system depicted in the schematic flow sheets of Figures 1 and 2 may need to be
modified, depending on the intended application (e.g. product vs. waste stream).
18185438_1 (GHMatters) P97118.NZ 23/10/21
Examples
Non-limiting Examples will now be described. Example 1 describes the context
of the method and system, and Examples 2 and 3 provide specific experimental
applications.
Example 1
Specific applications of the method and system were investigated in the area of
solid/liquid separation processes that relied on chemical coagulation and flocculation.
A specific field of investigation was gravitational thickeners in coal washeries as well as
gravitational thickeners in other types of mines. Other fields included sewage
treatment in relation to both gravitational clarifiers and biomass (sludge) dewatering,
mine tailings dewatering, and applications that required optimised flocculation of
slurries where variation in suspended particle surface charge occurred.
It was noted that, in the course of mining and washing coal, a significant
quantity of wastewater slurry was produced that contained high solids (e.g. >5%),
primarily in the form of coal fines and minerals (e.g. clay minerals, silicates, carbonates
and sulfur compounds), much of which were colloidal in nature (usually >20%).
This slurry was normally introduced into a gravitational thickener where high
molecular weight anionic (negatively charged) flocculant polymer was added to
facilitate particle agglomeration and settling. Flocculated solids settled to the bottom of
the thickener for subsequent removal, while the clarified water overflowed at the
perimeter for subsequent re-use in the coal washery.
It was noted that the flocculation was a complex process that depended on the
physical, chemical and electro-kinetic properties of the suspended particles, and
especially on the interaction of colloidal particles and ions in solution, as well as the pH
of the suspension. The flocculation involved a variety of mechanisms such as charge
neutralisation, polymer bridging and hydrogen bonding.
It was further noted that, for most coal mining operations, the application of low
to medium charge density anionic polyacrylamide flocculant to the coal slurry as it
entered the thickener usually gave good floc formation. This in turn resulted in fast
settling solids and sufficiently clarified overflow water for return to the washery for re-
use.
However, as the coal extraction/digging moved from one location to another
within the mine site, variations in the types and concentrations of suspended particles
18185438_1 (GHMatters) P97118.NZ 23/10/21
were experienced, along with variations in slurry pH. This typically caused the simple
flocculation to become less effective or sometimes completely ineffective, whereby
good separation of solid/liquid was not achieved, resulting in turbid water overflowing
from the thickener. Eventually, when this turbidity exceeded an acceptable limit for use
in washing coal, the plant was shut-down and production ceased, with financial
implications.
Whilst the deterioration in thickener performance when using anionic flocculant
could be overcome by the addition of a low molecular weight cationic coagulant prior to
flocculant addition, it was extremely difficult to determine and maintain an optimal
coagulant dose, due to the continually changing nature of the slurry feed to the
thickener.
Furthermore, it was noted that instrumentation for the automatic control of
flocculation in thickeners was ineffective in distinguishing deterioration in flocculation
performance due to a change in particle surface charge. For example, as the
anionicity of the influent slurry particles increased (e.g. more colloidal clay was
present), it was noted that the flocs became smaller and did not agglomerate well.
This resulted in an increase in settling time and worsening discharge turbidity. The
existing devices then responded to the slower settling rate by increasing polymer dose
rate, which made the situation worse due to the anionic nature of the flocculant
polymer.
In addition, it was noted that measuring the turbidity of water discharged from
the thickener, and using this value to control coagulant dosing, had an inherent time
delay in sensing a deterioration in flocculation performance, as retention time in the
thickener could be hours. Further, response time was too slow, and coagulant dosing
was not in accord with changing slurry characteristics during the lag time.
The method and system disclosed herein addressed and solved these
problems by continuously generating a measurement that reflected the net surface
charge present in the feed slurry to the thickener, or the particle quantity, and used that
value to automatically control coagulant addition to maintain optimal flocculation.
The method and system disclosed herein:
- continuously monitored particle surface charge of a filtrate or centrate using
streaming current or colourimeter technology to automatically control and optimise
flocculation;
- or used a turbidity meter to measure a figure indicative of particle quantity in
the filtrate or centrate;
18185438_1 (GHMatters) P97118.NZ 23/10/21
- utilised self-cleaning filtration or centrifugation technology (e.g. a sintered
metal cross-flow microfilter to supply a continuous flow of feed slurry filtrate at e.g. < 2
microns) to the meter, protecting the meter from fouling or abrasion by supplying a
relatively clean feed containing only very fine particles and colloids;
- found that a fine particle fraction of a wastewater slurry was representative of
the slurry as a whole in terms of net surface charge or particle quantity trends; in other
words, the filtrate or centrate was able to be used as a proxy for the whole slurry,
making use of the presence of charged colloidal particles in the filtrate or centrate;
- maintained the set point (as measured using the filtrate or centrate stream) by
automatic feedback control of coagulant dosing upstream, thereby optimising
flocculation conditions in the thickener.
Benefits of the method and system included:
- mine productivity increased due to less shutdowns caused by excessively
dirty water returning to the washery from the thickener;
- a more reliable solid/liquid separation performance was achieved in the
thickener due to improved flocculation control, even when feed slurry characteristics
frequently changed;
- a more consistent sludge was produced, which aided subsequent dewatering
processes (e.g. filter press);
- accurate and long-term operation of the meter by supplying to the instrument
a relatively clean non-fouling filtrate or centrate that still contained ions in solution and
colloidal particles;
- a filter or centrifuge device that continuously and automatically self-cleaned,
which made its use practical for mining and industrial settings;
- rapid detection of changes in particle surface charge or quantity due e.g. to an
increase in anionic clay colloids;
- automatic control of coagulant dosing in real time to maintain optimal
flocculation conditions for the wastewater slurry;
- data capture regarding measured values and coagulant dosing, which was
able to be used to better understand influent slurry characteristics and thickener
performance, and also enabled the correlation of slurry characteristics (e.g. high clay
content) with specific locations.
It should also be appreciated that benefits in addition to, or distinct from, those
identified above may be apparent, depending on the intended application of the
method and system disclosed herein.
18185438_1 (GHMatters) P97118.NZ 23/10/21
EXAMPLE 2
This experimental example was conducted to demonstrate the use of a
streaming current detector (SCD) to measure surface charge on colloidal and sub-
colloidal particles suspended in a coal slurry microfiltrate. It was used to further
demonstrate how this measurement can be used to control coagulant dosing to
maintain optimal flocculation and clarification in a thickener.
Two samples of coal slurry thickener feed were obtained from a New South
Wales coal preparation plant. The first slurry sample, designated Sample A, was able
to be readily flocculated when dosed with anionic polyacrylamide only (i.e. no
coagulant added), and good clarification was achieved (settled turbidity = 17.3 NTU).
The anionic polyacrylamide applied was the same as that used in the plant and was
characterised by the manufacturer as having a charge density of 5% and a molecular
weight of approximately 12 million Dalton. This flocculant was dosed at a
concentration of 0.25% and a rate of 3.0 ml/L.
The second slurry sample, designated Sample B, was also able to be
flocculated when dosed with anionic polyacrylamide only (applied as above), although
smaller flocs were formed, and these flocs settled more slowly than Sample A above.
In this case good clarification could not be achieved (settled turbidity = 293 NTU).
In laboratory trials, 250 ml of each of the above untreated slurry samples were
filtered on a Buchner funnel using <2 micron filter paper. A 200ml sample of each
microfiltrate thus obtained was measured for streaming current using a ChemTrac
Coagulant Charge Analyzer Model CCA3100. The initial streaming current value was
recorded, and then the microfiltrate was gradually titrated with a dilute cationic
coagulant solution (0.1% OptiFlox® Coagulant 325 polyDADMAC-polysaccharide
copolymer) to determine the charge demand of the microfiltrate. The results are set
out in Table 1 below:
Table 1
Sample A Sample B
Titrant Dose SCD Value Titrant Dose SCD Value
None -0.06 None -0.10
0.04 ml +0.04 0.04 ml -0.08
0.06 ml +0.07 0.06 ml -0.07
0.08 ml +0.11 0.08 ml -0.05
0.12 ml -0.03
0.16 ml -0.01
18185438_1 (GHMatters) P97118.NZ 23/10/21
The measured SCD value for Sample A rapidly increased in cationicity as the
titrant was added, whereas the SCD value for Sample B was slow to increase. This
data indicated that a higher cationic charge demand existed for Sample B, which in
turn indicated a higher total anionic surface charge present on the fine particles
suspended in Sample B.
When a coal tailings slurry was dosed with cationic coagulant, some of the
discrete anionic particles (e.g. clay colloids) that were present in the slurry
agglomerated with each other or with larger solid particles. When the slurry was then
subjected to microfiltration, some of these aggregates were retained in the slurry. This
caused a net reduction in both the quantity of particles present in the filtrate and their
total anionic surface charge, which in turn lowered the remaining cationic charge
demand of the slurry.
Therefore, by pre-determining an ideal set point for cationic charge demand
that resulted in optimal flocculation and clarification downstream, it was possible to use
the above method to control coagulant dosing upstream to maintain optimal charge
conditions.
In order to demonstrate this example of the method and system, 250 ml of
Sample B was first dosed with a quantity of coagulant (0.08 ml of 10% OptiFlox®
Coagulant 325 polyDADMAC-polysaccharide copolymer) that was previously
determined to enable optimal flocculation and clarification. This slurry was then filtered
on a Buchner funnel using <2 micron filter paper as before.
A 200ml sample of the microfiltrate thus obtained was measured for streaming
current using a ChemTrac Coagulant Charge Analyzer Model CCA3100. The initial
streaming current value was recorded, and then the microfiltrate was gradually titrated
with a dilute cationic coagulant solution (0.1% OptiFlox® Coagulant 325 polyDADMAC-
polysaccharide copolymer) to determine the charge demand of the microfiltrate. The
results are set out in Table 2 below:
Table 2
Treated Sample B (Pre-Dosed with
Coagulant)
Titrant Dose SCD Value
None -0.09
0.04 ml -0.01
0.06 ml +0.02
0.08 ml +0.04
18185438_1 (GHMatters) P97118.NZ 23/10/21
The measured SCD value for Treated Sample B (pre-dosed with coagulant)
now showed a faster increase in cationicity as the titrant was added than the original
untreated Sample B. This indicates a reduced cationic charge demand and lower total
anionic surface charge remaining in the microfiltrate, which also corresponds with
improved flocculation and clarification of the slurry as a whole.
To apply the above method for the control of flocculation in an actual coal
preparation plant thickener, required the following steps:
1. Install a continuous sampling, filtration and measuring device as set out in
Figure 1.
In this case, sampling should occur pre-flocculation (i.e. from the thickener feed
pipe).
2. Determine a fixed rate dose of titrant that produces SCD values in the desired
range.
3. Monitor filtrate SCD readings (charge demand) relative to thickener
performance in terms of flocculation and clarification efficacy.
4. Determine a filtrate SCD value or range that prevails when the thickener is
performing as desired.
. Program the controller to maintain the desired SCD set point or range via
output signals to the coagulant dosing pump. In other words, if the filtrate
charge demand SCD exceeded the set point or range, then coagulant would be
dosed upstream to effect a reduction in filtrate charge demand (as per the
above experimental example) until the desired SCD value is regained.
Therefore, by introducing a pre-determined fixed rate dose of titrant to a
continuous stream of microfiltrate and monitoring the SCD value, it was possible to
control and maintain a desired SCD set point via coagulant dosing upstream.
Automatically controlling the SCD value at the desired set point enabled surface
charge conditions to be maintained in the slurry, which in turn maintained flocculation
and clarification performance as desired in the thickener.
EXAMPLE 3
This experimental example was conducted to demonstrate the use of a
turbidimeter (turbidity meter) to measure the quantity of fine particles that remained
suspended in a filtrate of a flocculated coal slurry. The example further demonstrated
how this measurement was able to be used to control coagulant dosing to maintain
optimal flocculation and clarification in a thickener.
18185438_1 (GHMatters) P97118.NZ 23/10/21
Two samples of coal slurry thickener feed were obtained from a New South
Wales coal preparation plant. The first slurry sample, designated Sample C, was able
to be readily flocculated when dosed with anionic polyacrylamide only (i.e. no
coagulant added), and good clarification was achieved (settled turbidity = 21.8 NTU).
The anionic polyacrylamide applied was characterised by the manufacturer as having a
charge density of 5% and a molecular weight of approximately 12 million Dalton. This
flocculant was dosed at a concentration of 0.25% and a rate of 6.0 ml/L.
The second slurry sample, designated Sample D, was also able to be
flocculated when dosed with anionic polyacrylamide only (as above), although smaller
flocs were formed and these flocs settled more slowly than Sample C above. In this
case good clarification could not be achieved (settled turbidity = 382 NTU).
In laboratory trials, 100 ml of each of the above flocculated slurry samples
were filtered on a Buchner funnel using 8 micron filter paper. A 10 ml sample of each
filtrate thus obtained was charged to a cuvet and measured for turbidity using a Hanna
Instruments HI88703 Turbidity Meter. The results are set out in Table 3 below:
Table 3
Sample Turbidity of 8 micron filtrate (NTU)
C 3.46
D 29.3
Sample C exhibited a significantly lower filtrate turbidity than Sample D, which
indicated that a lesser quantity of fine particles were present in Sample C than Sample
D.
When a coal tailings slurry was dosed with cationic coagulant, some of the
discrete anionic particles (e.g. clay colloids) that were present in the slurry
agglomerated with each other or with larger solid particles. When the slurry was then
subjected to fine filtration, some of these aggregates were retained in the slurry. This
caused a net reduction in both the quantity of particles present in the filtrate and their
total anionic surface charge.
A net reduction in quantity of suspended particles was able to be measured by
a Turbidimeter. Therefore, once an ideal set point for filtrate turbidity of the flocculated
slurry was determined, upstream coagulant dosing enabled the turbidity set point to be
maintained.
In order to demonstrate this example of the method and system, a series of 100
ml aliquots of untreated Sample D were first dosed with increasing quantities of
coagulant (1% OptiFlox® Coagulant 325 polyDADMAC-polysaccharide copolymer) and
18185438_1 (GHMatters) P97118.NZ 23/10/21
then flocculated with anionic polyacrylamide as detailed above. The flocculated
slurries were then filtered on a Buchner funnel using 8 micron filter paper as before.
A 10 ml sample of each filtrate thus obtained was charged to a cuvet and
measured for turbidity using a Hanna Instruments HI88703 Turbidity Meter. The
results are set out in Table 4 below:
Table 4
Sample D (Pre-Dosed with Coagulant)
Coagulant Dose Turbidity of 8 micron filtrate
(NTU)
None 29.3
0.1 ml 20.6
0.2 ml 16.1
0.4 ml 7.10
0.8 ml 4.72
The data demonstrated that filtrate turbidity decreased as coagulant dosing
prior to flocculation increased. This indicated not only a reduction in fine particles
remaining in the filtrate, but also corresponded with improved flocculation and
clarification of the slurry as a whole.
To apply the above method for the control of flocculation in an actual coal
preparation plant thickener, required the following steps:
1. Install a continuous sampling, filtration and measuring device as set out in
Figure 2.
In this case, sampling should occur post-flocculation (i.e. from the thickener
feedwell).
2. Monitor filtrate turbidity readings relative to thickener performance in terms of
flocculation and clarification efficacy.
3. Determine a filtrate turbidity value or range that prevails when the thickener is
performing as desired.
4. Program the controller to maintain the desired turbidity set point or range via
output signals to the coagulant dosing pump. In other words, if the filtrate
turbidity exceeds the set point or range, then coagulant is dosed upstream to
effect a reduction in filtrate turbidity (as per the above experimental example)
until the desired turbidity is regained.
Therefore, by pre-determining an ideal filtrate turbidity set point or range for the
flocculated slurry (i.e. the value at which optimal flocculation and clarification was
18185438_1 (GHMatters) P97118.NZ 23/10/21
deemed to have occurred in the thickener), it was possible to control and maintain
thickener performance via simple automatic feedback control of coagulant dosing
upstream.
Whilst a number of specific method and system embodiments have been
described, it should be appreciated that the method and system may be embodied in
many other forms. For example, a colourimeter can be employed in place of the
streaming current detector. Also, a wide variety of wastewaters can be treated by the
filter/detect/feedback/dose method and system.
In the claims which follow, and in the preceding description, except where the
context requires otherwise due to express language or necessary implication, the word
“comprise” and variations such as “comprises” or “comprising” are used in an inclusive
sense, i.e. to specify the presence of the stated features but not to preclude the
presence or addition of further features in various embodiments of the method and
system as disclosed herein.
18185438_1 (GHMatters) P97118.NZ 23/10/21
Claims (5)
1. A method for treating a fluid stream that comprises particles of varying size suspended in the fluid stream, the method comprising: - obtaining a sample of a main or major flow of the fluid stream, the sample containing 5 the suspended particles of varying size in the fluid stream; - processing the sample to remove from the sample particles of the varying size that are above a certain size, to obtain an aliquot that contains suspended particles from the fluid stream that have a maximum particle size of less than 20 micrometres; - measuring in the aliquot one or more parameters that relate to quantity and/or charge 10 of the suspended particles from the fluid stream that have a size of less than 20 micrometres such that, when the one or more parameters deviate from a desired value, this indicates that the suspended particles of the varying size in the fluid stream require treatment; - using measurements of the one or more parameters to determine whether the 15 suspended particles of the varying size in the fluid stream require treatment; - selecting a chemical that is suitable for treating the suspended particles of the varying size in the fluid stream that require treatment; and - adding the chemical to the fluid stream. 20
2. A method as defined in claim 1, wherein the chemical is added to the fluid stream at a location upstream of where the sample is obtained.
3. A method as defined in claim 1 or 2, wherein a plurality of parameters are measured.
4. A method as claimed in any one of the preceding claims, wherein the desired value of the parameter(s) comprises a set point or a set range, and the treatment is continued until the measured parameter(s) in the aliquot return(s) to the set point or set range.
5. A method as claimed in any one of the preceding claims, wherein the parameter(s) deviate(s) from the desired value when particles of varying size suspended in the fluid stream are such as to render the stream unsuitable for the treatment regime. 18185438_1 (GHMatters) P97118.NZ
Applications Claiming Priority (3)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| AU2014903635 | 2014-09-11 | ||
| AU2014903635A AU2014903635A0 (en) | 2014-09-11 | Wastewater Measurement and Treatment | |
| PCT/AU2015/000564 WO2016037227A1 (en) | 2014-09-11 | 2015-09-11 | Measurement and treatment of fluid streams |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| NZ729151A NZ729151A (en) | 2021-11-26 |
| NZ729151B2 true NZ729151B2 (en) | 2022-03-01 |
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