SIST ISO 923:2002
(Main)Coal cleaning equipment -- Performance evaluation
Coal cleaning equipment -- Performance evaluation
This International Standard describes the principles and methods for evaluating the performance of equipment
used for cleaning operations. Testing and sampling procedures are specified and methods of presenting test
results are detailed. Performance parameters are recommended and defined and their determination is formulated,
thereby allowing their use in evaluating, comparing and predicting performance levels of cleaning operations.
This International Standard is applicable to the following types of coal cleaning equipment using relative density as
the main characteristic for separation:
a) dense-medium separators;
b) jigs;
c) other separators.
Équipement pour l'épuration du charbon -- Évaluation des résultats
Oprema za separiranje premoga - Preskušanje in vrednotenje učinkovitosti delovanja
General Information
Relations
Standards Content (Sample)
SLOVENSKI STANDARD
SIST ISO 923:2002
01-januar-2002
2SUHPD]DVHSDULUDQMHSUHPRJD3UHVNXãDQMHLQYUHGQRWHQMHXþLQNRYLWRVWL
GHORYDQMD
Coal cleaning equipment -- Performance evaluation
Équipement pour l'épuration du charbon -- Évaluation des résultats
Ta slovenski standard je istoveten z: ISO 923:2000
ICS:
73.120 Oprema za predelavo rudnin Equipment for processing of
minerals
SIST ISO 923:2002 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.
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SIST ISO 923:2002
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SIST ISO 923:2002
INTERNATIONAL ISO
STANDARD 923
Second edition
2000-05-15
Coal cleaning equipment — Performance
evaluation
Équipement pour l'épuration du charbon — Évaluation des résultats
Reference number
ISO 923:2000(E)
©
ISO 2000
---------------------- Page: 3 ----------------------
SIST ISO 923:2002
ISO 923:2000(E)
PDF disclaimer
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be edited unless the typefaces which are embedded are licensed to and installed on the computer performing the editing. In downloading this
file, parties accept therein the responsibility of not infringing Adobe's licensing policy. The ISO Central Secretariat accepts no liability in this
area.
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Details of the software products used to create this PDF file can be found in the General Info relative to the file; the PDF-creation parameters
were optimized for printing. Every care has been taken to ensure that the file is suitable for use by ISO member bodies. In the unlikely event
that a problem relating to it is found, please inform the Central Secretariat at the address given below.
© ISO 2000
All rights reserved. Unless otherwise specified, no part of this publication may be reproduced or utilized in any form or by any means, electronic
or mechanical, including photocopying and microfilm, without permission in writing from either ISO at the address below or ISO's member body
in the country of the requester.
ISO copyright office
Case postale 56 � CH-1211 Geneva 20
Tel. + 41 22 749 01 11
Fax + 41 22 734 10 79
E-mail copyright@iso.ch
Web www.iso.ch
Printed in Switzerland
ii © ISO 2000 – All rights reserved
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SIST ISO 923:2002
ISO 923:2000(E)
Contents Page
Foreword.iv
1 Scope .1
2 Normative references .1
3 Terms and definitions .1
4 Performance criteria.2
5 Performance parameters .2
6 Performance test procedures.3
7 Analytical procedures .3
8 Expression of performance .3
Annex A (normative) Methods of expressing performance.4
Annex B (normative) Recommendations for standard methods of presenting coal cleaning test data.5
Annex C (informative) Graphs.29
© ISO 2000 – All rights reserved iii
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SIST ISO 923:2002
ISO 923:2000(E)
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards bodies (ISO
member bodies). The work of preparing International Standards is normally carried out through ISO technical
committees. Each member body interested in a subject for which a technical committee has been established has
the right to be represented on that committee. International organizations, governmental and non-governmental, in
liaison with ISO, also take part in the work. ISO collaborates closely with the International Electrotechnical
Commission (IEC) on all matters of electrotechnical standardization.
International Standards are drafted in accordance with the rules given in the ISO/IEC Directives, Part 3.
Draft International Standards adopted by the technical committees are circulated to the member bodies for voting.
Publication as an International Standard requires approval by at least 75 % of the member bodies casting a vote.
Attention is drawn to the possibility that some of the elements of this International Standard may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights.
International Standard ISO 923 was prepared by Technical Committee ISO/TC 27, Solid mineral fuels,
Subcommittee SC 1, Coal preparation: Terminology and performance.
This second edition cancels and replaces the first edition (ISO 923:1975), which has been technically revised.
Annexes A and B form a normative part of this International Standard. Annex C is for information only.
iv © ISO 2000 – All rights reserved
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SIST ISO 923:2002
INTERNATIONAL STANDARD ISO 923:2000(E)
Coal cleaning equipment — Performance evaluation
1 Scope
This International Standard describes the principles and methods for evaluating the performance of equipment
used for cleaning operations. Testing and sampling procedures are specified and methods of presenting test
results are detailed. Performance parameters are recommended and defined and their determination is formulated,
thereby allowing their use in evaluating, comparing and predicting performance levels of cleaning operations.
This International Standard is applicable to the following types of coal cleaning equipment using relative density as
the main characteristic for separation:
a) dense-medium separators;
b) jigs;
c) other separators.
2 Normative references
The following normative documents contain provisions which, through reference in this text, constitute provisions of
this International Standard. For dated references, subsequent amendments to, or revisions of, any of these
publications do not apply. However, parties to agreements based on this International Standard are encouraged to
investigate the possibility of applying the most recent editions of the normative documents indicated below. For
undated references, the latest edition of the normative document referred to applies. Members of ISO and IEC
maintain registers of currently valid International Standards.
ISO 1170, Coal and coke — Calculation of analyses to different bases.
ISO 1213-1, Solid mineral fuels — Vocabulary — Part 1: Terms relating to coal preparation.
ISO 1953, Hard coal — Size analysis by sieving.
ISO 1988, Hard coal — Sampling.
ISO 5048, Continuous mechanical handling equipment — Belt conveyors with carrying idlers — Calculation of
operating power and tensile forces.
ISO 7936, Hard coal — Determination and presentation of float and sink characteristics — General directions for
apparatus and procedures.
3 Terms and definitions
For the purposes of this International Standard, the terms and definitions given in ISO 1213-1 apply.
© ISO 2000 – All rights reserved 1
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SIST ISO 923:2002
ISO 923:2000(E)
4 Performance criteria
The following criteria are used:
a) the feed rate, expressed on mass and/or volume basis;
b) reference density of separation;
c) sharpness of separation;
d) correctly placed and misplaced material;
e) ash error and yield error;
f) the degree of difficulty of separation;
g) material characteristics.
The above criteria will be influenced by test conditions, which should therefore be fully reported.
Conditions, including feed rate, should be kept uniform, monitored and maintained within prescribed tolerance limits
during a test.
Where performance test results are used for prediction, process conditions should be taken into account.
5 Performance parameters
For the standard expression of performance of a cleaning operation, determine the criteria in clause 4 by the
following parameters:
a) the feed rate, expressed on mass and/or volume basis;
Keep the feed rate as uniform as possible throughout the performance test and determine it over the duration
of the test by the most accurate method available.
Where the feed to the equipment is by belt conveyor, determine the feed rate in accordance with ISO 5048.
b) the reference density of separation, preferably expressed as both partition density and equal-errors cut-point
(density);
c) the sharpness of separation expressed in terms of probable error and imperfection;
d) the distribution of correctly placed and incorrectly placed material in each product, presented graphically with
respect to relative density, and the particular value of misplaced material in each product, determined at the
reference density of separation;
e) the ash error expressed as the difference between the actual ash in the cleaned coal and the theoretical ash at
the actual yield value;
f) the yield error expressed as the difference between the actual yield and the theoretical yield at the actual
clean-coal ash value;
g) the degree of difficulty of separation expressed in terms of near-density material (and by other relevant
characteristics).
2 © ISO 2000 – All rights reserved
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SIST ISO 923:2002
ISO 923:2000(E)
6 Performance test procedures
The equipment to be tested, the feed composition, and the means of handling the feed and products, vary widely. A
single International Standard to cover all cases is not applicable. The following general procedures shall be
followed.
a) Samples shall be taken from the feed and from each of the products. The sampling techniques, number of
increments and increment mass shall ensure that all samples taken are representative and shall comply with
existing International Standards where available. Sampling of coal is covered by ISO 1988 and size analysis of
coal is covered by ISO 1953.
To enable checking of results and assessment of the effects of degradation, representative samples should be
taken from all relevant streams to and from the equipment to be tested.
b) It is essential to determine the feed rate and the percentage yield to each of the products on a dry basis in
accordance with ISO 1170. This should be achieved in accordance with one of the procedures given below.
Determine the mass of each product by one or more of the following methods, which are listed in order of reliability.
a) By direct weighing of the whole of each product collected over the duration of the test or through continuous
weighing and integration over the duration of the test.
b) By taking regular timed increments over the duration of the test.
c) By weighing each product collected simultaneously over a selected period of the test.
NOTE 1 If it is feasible to measure both the mass of the feed (by belt weigher, weigh hopper, flowmeter, etc.) and the mass
of the products, this provides a check.
NOTE 2 If the mass of one of the products cannot be obtained, it may be derived from a mass balance between the feed and
other product(s).
NOTE 3 Where the solids are conveyed by a fluid, it may be more convenient to make volumetric measurements.
Representative samples should be taken from streams to determine moisture content or concentrations of solids as
appropriate, so that results can be reported on a dry basis.
In circumstances that prevent the determination of yields by the above procedures, alternative procedures (e.g. ash
balance) may be used.
7 Analytical procedures
The methods and procedures of size analysis and float and sink analysis shall be in accordance with ISO 1953 and
ISO 7936, respectively.
The feed sample and each of the product samples should be separated into various particle size fractions
depending on the degree of detail required. Because the performance of coal cleaning equipment is usually
different for different size particles, the size ranges should be as prescribed in ISO 7936.
8 Expression of performance
Methods for the expression of the results of coal cleaning tests and the performance of the separation processes
are given in normative annex A.
For the purpose of meeting the requirements stated in clause 1, no single method suffices by itself.
Normative annex B describes recommended methods for the calculation and tabulation of test results, and informative
annex C gives graphical presentations.
© ISO 2000 – All rights reserved 3
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SIST ISO 923:2002
ISO 923:2000(E)
Annex A
(normative)
Methods of expressing performance
Formula Derived from Remarks
A.1
Separation density Describes one characteristic of the separation, but does not
indicate its accuracy
a) Partition density Partition curves
b) Equal-errors cut-point M-curves
(density) Washability curves
A.2 Misplaced material M-curves Measure of quantity of misplaced material (without reference
Washability curves to its quality) at the separation density
A.3 Total of correctly placed M-curves Measure of quantity of correctly placed material (without
material Washability curves reference to its quality) at the separation density
A.4 Ash error M-curves Reflects both the quantity and quality of misplaced material in
Washability curves terms of the specific property of coal (percentage of ash) that
the separation is designed to control; measures qualitative
efficiency
A.5
Yield error M-curves Reflects both the quantity and quality of misplaced material
Washability curves and measures quantitative efficiency
A.6 Organic efficiency M-curves Related to yield error but expressed as a percentage
Washability curves
A.7 Error area Partition curves Measure of quantity of misplaced material in terms of density
A.8 Partition coefficients Partition curves Special applications only
A.9 Écart probable (moyen)
Partition curves Gives an indication of the quantitative errors inherent in the
separating process at a given separation density
A.10 Imperfection Partition curves Modification of écart probable (moyen) to include effect of
varying separation density. Not used for dense-medium
separators
A.11
Yield loss Product samples States results without reference to accuracy of separation
NOTE 1 M-curves and washability curves describe graphically the character of the raw coal and of the products, in terms of mass and ash.
Partition curves describe only the products in terms of mass and density; they can be constructed without the necessity to determine ash.
NOTE 2 M-curves have wider direct applications than washability curves, especially, for example, in three-product separations. The
construction of such curves is described in ISO 7936.
NOTE 3 The écart probable (moyen) and imperfection reflect the influence of changes in the separation process rather than in the raw coal,
in contrast to the formulae derived from M-curves or washability curves, which reflect changes in the raw coal as well as in the separation
process.
NOTE 4 The separation density, although not a measure of efficiency, is an important characteristic of the separation and is essential to any
comprehensive statement of the results of a given test.
NOTE 5 The misplaced material and the total of correctly placed material at the separation density, the ash error, the yield error, the organic
efficiency and the error area can all be used for guarantee tests and occasional control tests to give an indication of the accuracy of a given
separation on a given coal, and hence of economic efficiency; but they are of little value in the prediction of probable results of cleaning a
range of coals by one specific process.
NOTE 6 Partition coefficients, écart probable (moyen) and imperfection are valuable for the purpose of prediction but do not give an
adequate indication of the accuracy of a given separating operation on a particular coal.
4 © ISO 2000 – All rights reserved
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SIST ISO 923:2002
ISO 923:2000(E)
Annex B
(normative)
Recommendations for standard methods of presenting coal cleaning test
data
B.1 Description of the tables
Two sets of tables are required (see clauses B.4 to B.7):
a) for three-product separation (cleaned coal, middlings and reject);
b) for two-product separation (cleaned coal and reject).
For convenience, an identical layout has been adopted for both sets of tables but, in those intended for use with
two-product separations, the columns that relate only to three-product separation have been left blank to avoid
confusion.
Each set of tables is presented in two ways.
a) Blank tables, to show the method of printing (see Form 1 and Form 3 in clauses B.4 and B.6, respectively).
b) Tables completed by filling in the figures relating to test results. For example, Form 2 and Form 4 shown in
clauses B.5 and B.7 give the results of a test using a Baum jig washer.
NOTE The example described in this annex was carried out prior to the publication of ISO 7936. The particle sizes used
therefore are not in accordance with those specified in that International Standard.
For the test described in this example, the washer was supplied with coal sized from 152 mm to 0 mm. The figures
used refer to the fraction sized between 12,7 mm and 0,5 mm. The fine material below 0,5 mm was removed from
the samples before carrying out float and sink tests, because this fine material presents difficulties in testing.
Moreover, the jig is not expected to clean material smaller than 0,5 mm.
For a full analysis of the test, tables similar to those given for the 12,7 mm to 0,5 mm size would be required for the
other sizes of the raw coal, in this instance 152 mm to 51 mm, 51 mm to 25,4 mm, and 25,4 mm to 12,7 mm. Such
tables would enable the performance on the different sizes to be compared. By adding together the results on the
four individual sizes, a further set of tables could be constructed giving cumulative data for the whole of the 152 mm
to 0,5 mm coal.
In this test, three products were made: cleaned coal, middlings and reject. The reject is the material removed by the
primary reject elevator and the middlings is the reject from the secondary reject elevator. The tables headed "three-
product separation" are built up from float and sink tests at various relative densities from 1,30 to 2,20 on samples
of each of these three products. Although intervals of 0,1 relative density have been used for the example, different
ranges and intervals may be required in other cases.
The figures in the tables headed "two-product separation" have been calculated from these same figures on the
assumption that the products from both elevators (i.e. the middlings and the reject) were combined so that there
were two products only: cleaned coal and a single reject.
© ISO 2000 – All rights reserved 5
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SIST ISO 923:2002
ISO 923:2000(E)
B.2 Expression of efficiency in the three-product separation
Three-product separation may be regarded as a combination of two distinct two-product separations (i.e. a low-
density cut and a high-density cut), whether these two stages are in fact carried out in different separating vessels
or in different parts of the same vessel.
The diagrams in Figure B.1 illustrate different combinations of the two stages.
Key
F Feed (reconstituted raw coal)
C Cleaned coal
R Reject
M Intermediate product (middlings)
Figure B.1
Diagrams 1 and 2 represent typical arrangements for a two-stage dense-medium separation, the only difference
being that the low-density cut comes first in diagram 1 and second in diagram 2, whereas diagram 3 represents a
normal three-product jig (or a three-product dense-medium separation). The middlings M may be collected as a
separate product, or recirculated, or otherwise dealt with, but provided that any recirculated middlings are included
in the reconstituted feed F, the argument is unaffected.
The efficiency of a three-product separation may be calculated in two different ways:
a) Method A, by regarding it as two distinct and individual separations, each with its own feed;
b) Method B, by regarding it as a single comprehensive separation, the feed for which is the reconstituted raw
coal.
To calculate the partition coefficients, the appropriate formulae for these two methods, for the combinations of plant
illustrated in the diagrams, are as follows:
For diagram 1
100 (MR� )
a) Method A: low-density cut
CM��R
100 R
high-density cut
CM��R
100 (MR� )
b) Method B: low-density cut
CM��R
100 M
high-density cut
CM��R
6 © ISO 2000 – All rights reserved
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SIST ISO 923:2002
ISO 923:2000(E)
For diagram 2
100 R
a) Method A: high-density cut
CM��R
100 M
low-density cut
CM�
100 R
b) Method B: high-density cut
CM��R
100 M
low-density cut
CM��R
For diagram 3
100 R
a) Method A: high-density cut
CM��R
100 M
low-density cut
CM�
100 R
b) Method B: high-density cut
CM��R
100 (MR� )
low-density cut
CM��R
Although for Method A the formulae are identical for diagrams 2 and 3, in the latter case there is no sharp dividing
line between the first and second cuts. The first (high-density) cut separates the reject R from the combination of
the cleaned coal C and middlings M, and it is this combination that becomes the feed to the second stage of the
separation.
Method A enables the efficiency of each of the two separations to be studied individually, because only the material
actually admitted to the separation is included in the calculation. This is of advantage when considering the
performance of each machine or stage in the separation process.
Method B does not show up so emphatically the actual performance of the second machine or stage, but by
referring each separation back to the reconstituted raw feed it facilitates comparisons of the efficiency of the whole
separation process in terms of the results on the original raw coal. (The sequence of operations included in this
complete process may include steps not shown in diagrams 1 to 3, for example crushing of the middlings and its
recirculation to the feed, which is common in jig washing and may also occur in dense-medium separation.)
It is essential, whenever the efficiency of a three-product separation is expressed (for example, in descriptions of
plant and efficiency statements and guarantees), that it be clearly stated which of these two bases has been used
for the calculation. To facilitate this, it is proposed that Method A be described as the equipment performance
basis, and Method B as the coal performance basis.
Tables B.1 to B.10 for the three-product separations are drawn up on the coal performance basis. When
calculations are made on the equipment performance basis, it is recommended that two-product tables be used
(one for each stage). It is possible, however, to deduce the results from the three-product table; thus, partition
coefficients for the second cut would be calculated on the equipment performance basis as follows:
a) for diagram 1 (see Figure B.1 in clause B.2), column (12) would be calculated from (7)/(9) instead of (7)/(10) in
Table B.7;
b) for diagrams 2 and 3 (see Figure B.1 in clause B.2), column (13) would be calculated from (6)/(8) instead of
(9)/(10) in Table B.7.
© ISO 2000 – All rights reserved 7
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SIST ISO 923:2002
ISO 923:2000(E)
B.3 Descriptions of the graphs (see annex C)
B.3.1 Introduction
To calculate the efficiency, the data required in clause B.4 (Tables B.1 to B.5) and clause B.6 (Tables B.11 to B.15)
should be represented in graphs. Graphs relating to the test results in clause B.5 (Tables B.6 to B.10) and in clause
B.7 (Tables B.16 to B.20) are shown in Figures C.1 to C.4. The graphs have been prepared from the data for three-
product separation; but the curves for the low-density cut apply to the two-product example.
Figure C.1 has been drawn to such a scale that 0,2 unit on the relative density axis equals 10 % on the partition-
coefficient axis. It is proposed to standardize this relation for drawing partition curves, when using (as in Figure C.1)
linear coordinates, but similar standard scales for the other curves are not considered to be practicable at present.
The curves can also be drawn using coordinates that are other than linear.
The construction and use of the graphs in Figures C.1 to C.4 are explained in B.3.2 to B.3.5.
B.3.2 Partition curves (three-product) (see Figure C.1)
The partition coefficients in columns (12) and (13) in Table B.7 are plotted against the mean of the relative densities
shown in Table B.7 for each fraction.
The curve on the right of Figure C.1 represents the high-density cut because it refers to the removal of the final reject.
The table columns from which the coefficients are extracted are shown on each curve.
The relative density at which the curves cross 50 % is by definition the partition density. Similarly, écart probable
(moyen) (Epm) is defined in terms of the relative densities d and d at which the curves cross 25 % and 75 %
25 75
respectively. The imperfection (I) is derived from these as shown.
B.3.3 Ash error and organic efficiency (see Figure C.2)
The curve in Figure C.2 shows the cumulative mass on the reconstituted feed plotted against the cumulative ash
percent, the figures being taken from columns (43) and (45) in Table B.10.
The point X represents the actual yield and ash for the high-density cut (total cleaned coal and middlings), and the
point Y represents those for the low-density cut (total cleaned coal).
Regarding point X.
� The actual ash is 5,61 % and the theoretical float and sink ash for the actual yield of 93,4 % as given by the
curve is 5,05 %. The ash error is the difference between these two ash percentages.
� The actual yield is 93,40 % at 5,61 % ash. The theoretical float and sink yield for 5,61 % ash is given by the
curve as 94,60 %. The organic efficiency is derived from the ratio of these two yields.
Similar considerations apply to point Y.
B.3.4 Correctly placed (and misplaced) material — High-density cut (see Figure C.3)
The two lower curves in Figure C.3 show the amounts of misplaced material in the reject (column 18 in Table B.8)
and the cleaned coal plus middlings product (column 17 in Table B.8), the fraction which in this example goes
forward for further treatment. The upper curve shows the sum or total of the misplaced material in these two
products combined (column 19 in Table B.8). The total amount (percentage) of correctly placed material (100
minus misplaced material) is read from the scale on the right-hand side of the graph.
The equal-errors cut-point (density) is the relative density at which the two lower curves intersect; in this example, this
density is 1,770. The partition density is 1,835.
8 © ISO 2000 – All rights reserved
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SIST ISO 923:2002
ISO 923:2000(E)
The relative densities of 1,770 and 1,835 correspond respectively to 96,6 % and 96,7 % for the amounts of correctly
placed material.
B.3.5 Correctly placed (and misplaced) material — Low-density cut (see Figure C.4)
The same considerations apply as for the high-density cut, the amounts of misplaced materials in each product
being plotted from columns (23) and (24) and the total from column (25) in Table B.8. The equal-errors cut-point
(density) and the partition densities are 1,400 and 1,505 and the amounts of correctly placed material 89,9 % and
91,0 % respectively.
The curves in Figures C.1 to C.4 have been drawn on the coal performance basis, all yields being expressed as a
percentage of the reconstituted raw coal. On the equipment performance basis, the washing operation being
regarded as two distinct two-product separations, the construction of the curves follows exactly the same method
as for any two-product separation and presents no difficulties. The curves that apply to the high-density cut
(Figure C.1: lower curve; Figure C.2: point X; Figure C.3: upper curve) are identical for both bases.
B.4 Form 1 — Tables for three-product separation
Table B.1 — Data required for calculation of efficiency of three/two-product separation
Reference: Date of test: Name of plant:
Test details Mass Summary results
(1) Single cut: Actual products
Size of coal analyzed, Size Total feed to (see note)
mm analyzed plant Cleaned coal
Reject
(1) High-density cut:
Size of feed to plant,
Cleaned coal + Middlings/Reject
t% t%
mm
(2) Low-density cut:
Cleaned coal/Middlings + Reject
Raw
Type of cleaning unit coal
treated
Products Separating Correctly
density placed
Rated capacity, t/h
material
Cleaned
%
coal
Middings (1) (2) (1) (2)
Seam(s) treated Partition
Reject
Equal errors
h Feed rate, t/h
b
Actual testing period
Epm
min
a
Basis of masses: Dry
h
a
Air dry
Total stoppages Imperfection
min
...
INTERNATIONAL ISO
STANDARD 923
Second edition
2000-05-15
Coal cleaning equipment — Performance
evaluation
Équipement pour l'épuration du charbon — Évaluation des résultats
Reference number
ISO 923:2000(E)
©
ISO 2000
---------------------- Page: 1 ----------------------
ISO 923:2000(E)
PDF disclaimer
This PDF file may contain embedded typefaces. In accordance with Adobe's licensing policy, this file may be printed or viewed but shall not
be edited unless the typefaces which are embedded are licensed to and installed on the computer performing the editing. In downloading this
file, parties accept therein the responsibility of not infringing Adobe's licensing policy. The ISO Central Secretariat accepts no liability in this
area.
Adobe is a trademark of Adobe Systems Incorporated.
Details of the software products used to create this PDF file can be found in the General Info relative to the file; the PDF-creation parameters
were optimized for printing. Every care has been taken to ensure that the file is suitable for use by ISO member bodies. In the unlikely event
that a problem relating to it is found, please inform the Central Secretariat at the address given below.
© ISO 2000
All rights reserved. Unless otherwise specified, no part of this publication may be reproduced or utilized in any form or by any means, electronic
or mechanical, including photocopying and microfilm, without permission in writing from either ISO at the address below or ISO's member body
in the country of the requester.
ISO copyright office
Case postale 56 � CH-1211 Geneva 20
Tel. + 41 22 749 01 11
Fax + 41 22 734 10 79
E-mail copyright@iso.ch
Web www.iso.ch
Printed in Switzerland
ii © ISO 2000 – All rights reserved
---------------------- Page: 2 ----------------------
ISO 923:2000(E)
Contents Page
Foreword.iv
1 Scope .1
2 Normative references .1
3 Terms and definitions .1
4 Performance criteria.2
5 Performance parameters .2
6 Performance test procedures.3
7 Analytical procedures .3
8 Expression of performance .3
Annex A (normative) Methods of expressing performance.4
Annex B (normative) Recommendations for standard methods of presenting coal cleaning test data.5
Annex C (informative) Graphs.29
© ISO 2000 – All rights reserved iii
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ISO 923:2000(E)
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards bodies (ISO
member bodies). The work of preparing International Standards is normally carried out through ISO technical
committees. Each member body interested in a subject for which a technical committee has been established has
the right to be represented on that committee. International organizations, governmental and non-governmental, in
liaison with ISO, also take part in the work. ISO collaborates closely with the International Electrotechnical
Commission (IEC) on all matters of electrotechnical standardization.
International Standards are drafted in accordance with the rules given in the ISO/IEC Directives, Part 3.
Draft International Standards adopted by the technical committees are circulated to the member bodies for voting.
Publication as an International Standard requires approval by at least 75 % of the member bodies casting a vote.
Attention is drawn to the possibility that some of the elements of this International Standard may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights.
International Standard ISO 923 was prepared by Technical Committee ISO/TC 27, Solid mineral fuels,
Subcommittee SC 1, Coal preparation: Terminology and performance.
This second edition cancels and replaces the first edition (ISO 923:1975), which has been technically revised.
Annexes A and B form a normative part of this International Standard. Annex C is for information only.
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INTERNATIONAL STANDARD ISO 923:2000(E)
Coal cleaning equipment — Performance evaluation
1 Scope
This International Standard describes the principles and methods for evaluating the performance of equipment
used for cleaning operations. Testing and sampling procedures are specified and methods of presenting test
results are detailed. Performance parameters are recommended and defined and their determination is formulated,
thereby allowing their use in evaluating, comparing and predicting performance levels of cleaning operations.
This International Standard is applicable to the following types of coal cleaning equipment using relative density as
the main characteristic for separation:
a) dense-medium separators;
b) jigs;
c) other separators.
2 Normative references
The following normative documents contain provisions which, through reference in this text, constitute provisions of
this International Standard. For dated references, subsequent amendments to, or revisions of, any of these
publications do not apply. However, parties to agreements based on this International Standard are encouraged to
investigate the possibility of applying the most recent editions of the normative documents indicated below. For
undated references, the latest edition of the normative document referred to applies. Members of ISO and IEC
maintain registers of currently valid International Standards.
ISO 1170, Coal and coke — Calculation of analyses to different bases.
ISO 1213-1, Solid mineral fuels — Vocabulary — Part 1: Terms relating to coal preparation.
ISO 1953, Hard coal — Size analysis by sieving.
ISO 1988, Hard coal — Sampling.
ISO 5048, Continuous mechanical handling equipment — Belt conveyors with carrying idlers — Calculation of
operating power and tensile forces.
ISO 7936, Hard coal — Determination and presentation of float and sink characteristics — General directions for
apparatus and procedures.
3 Terms and definitions
For the purposes of this International Standard, the terms and definitions given in ISO 1213-1 apply.
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ISO 923:2000(E)
4 Performance criteria
The following criteria are used:
a) the feed rate, expressed on mass and/or volume basis;
b) reference density of separation;
c) sharpness of separation;
d) correctly placed and misplaced material;
e) ash error and yield error;
f) the degree of difficulty of separation;
g) material characteristics.
The above criteria will be influenced by test conditions, which should therefore be fully reported.
Conditions, including feed rate, should be kept uniform, monitored and maintained within prescribed tolerance limits
during a test.
Where performance test results are used for prediction, process conditions should be taken into account.
5 Performance parameters
For the standard expression of performance of a cleaning operation, determine the criteria in clause 4 by the
following parameters:
a) the feed rate, expressed on mass and/or volume basis;
Keep the feed rate as uniform as possible throughout the performance test and determine it over the duration
of the test by the most accurate method available.
Where the feed to the equipment is by belt conveyor, determine the feed rate in accordance with ISO 5048.
b) the reference density of separation, preferably expressed as both partition density and equal-errors cut-point
(density);
c) the sharpness of separation expressed in terms of probable error and imperfection;
d) the distribution of correctly placed and incorrectly placed material in each product, presented graphically with
respect to relative density, and the particular value of misplaced material in each product, determined at the
reference density of separation;
e) the ash error expressed as the difference between the actual ash in the cleaned coal and the theoretical ash at
the actual yield value;
f) the yield error expressed as the difference between the actual yield and the theoretical yield at the actual
clean-coal ash value;
g) the degree of difficulty of separation expressed in terms of near-density material (and by other relevant
characteristics).
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ISO 923:2000(E)
6 Performance test procedures
The equipment to be tested, the feed composition, and the means of handling the feed and products, vary widely. A
single International Standard to cover all cases is not applicable. The following general procedures shall be
followed.
a) Samples shall be taken from the feed and from each of the products. The sampling techniques, number of
increments and increment mass shall ensure that all samples taken are representative and shall comply with
existing International Standards where available. Sampling of coal is covered by ISO 1988 and size analysis of
coal is covered by ISO 1953.
To enable checking of results and assessment of the effects of degradation, representative samples should be
taken from all relevant streams to and from the equipment to be tested.
b) It is essential to determine the feed rate and the percentage yield to each of the products on a dry basis in
accordance with ISO 1170. This should be achieved in accordance with one of the procedures given below.
Determine the mass of each product by one or more of the following methods, which are listed in order of reliability.
a) By direct weighing of the whole of each product collected over the duration of the test or through continuous
weighing and integration over the duration of the test.
b) By taking regular timed increments over the duration of the test.
c) By weighing each product collected simultaneously over a selected period of the test.
NOTE 1 If it is feasible to measure both the mass of the feed (by belt weigher, weigh hopper, flowmeter, etc.) and the mass
of the products, this provides a check.
NOTE 2 If the mass of one of the products cannot be obtained, it may be derived from a mass balance between the feed and
other product(s).
NOTE 3 Where the solids are conveyed by a fluid, it may be more convenient to make volumetric measurements.
Representative samples should be taken from streams to determine moisture content or concentrations of solids as
appropriate, so that results can be reported on a dry basis.
In circumstances that prevent the determination of yields by the above procedures, alternative procedures (e.g. ash
balance) may be used.
7 Analytical procedures
The methods and procedures of size analysis and float and sink analysis shall be in accordance with ISO 1953 and
ISO 7936, respectively.
The feed sample and each of the product samples should be separated into various particle size fractions
depending on the degree of detail required. Because the performance of coal cleaning equipment is usually
different for different size particles, the size ranges should be as prescribed in ISO 7936.
8 Expression of performance
Methods for the expression of the results of coal cleaning tests and the performance of the separation processes
are given in normative annex A.
For the purpose of meeting the requirements stated in clause 1, no single method suffices by itself.
Normative annex B describes recommended methods for the calculation and tabulation of test results, and informative
annex C gives graphical presentations.
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ISO 923:2000(E)
Annex A
(normative)
Methods of expressing performance
Formula Derived from Remarks
A.1
Separation density Describes one characteristic of the separation, but does not
indicate its accuracy
a) Partition density Partition curves
b) Equal-errors cut-point M-curves
(density) Washability curves
A.2 Misplaced material M-curves Measure of quantity of misplaced material (without reference
Washability curves to its quality) at the separation density
A.3 Total of correctly placed M-curves Measure of quantity of correctly placed material (without
material Washability curves reference to its quality) at the separation density
A.4 Ash error M-curves Reflects both the quantity and quality of misplaced material in
Washability curves terms of the specific property of coal (percentage of ash) that
the separation is designed to control; measures qualitative
efficiency
A.5
Yield error M-curves Reflects both the quantity and quality of misplaced material
Washability curves and measures quantitative efficiency
A.6 Organic efficiency M-curves Related to yield error but expressed as a percentage
Washability curves
A.7 Error area Partition curves Measure of quantity of misplaced material in terms of density
A.8 Partition coefficients Partition curves Special applications only
A.9 Écart probable (moyen)
Partition curves Gives an indication of the quantitative errors inherent in the
separating process at a given separation density
A.10 Imperfection Partition curves Modification of écart probable (moyen) to include effect of
varying separation density. Not used for dense-medium
separators
A.11
Yield loss Product samples States results without reference to accuracy of separation
NOTE 1 M-curves and washability curves describe graphically the character of the raw coal and of the products, in terms of mass and ash.
Partition curves describe only the products in terms of mass and density; they can be constructed without the necessity to determine ash.
NOTE 2 M-curves have wider direct applications than washability curves, especially, for example, in three-product separations. The
construction of such curves is described in ISO 7936.
NOTE 3 The écart probable (moyen) and imperfection reflect the influence of changes in the separation process rather than in the raw coal,
in contrast to the formulae derived from M-curves or washability curves, which reflect changes in the raw coal as well as in the separation
process.
NOTE 4 The separation density, although not a measure of efficiency, is an important characteristic of the separation and is essential to any
comprehensive statement of the results of a given test.
NOTE 5 The misplaced material and the total of correctly placed material at the separation density, the ash error, the yield error, the organic
efficiency and the error area can all be used for guarantee tests and occasional control tests to give an indication of the accuracy of a given
separation on a given coal, and hence of economic efficiency; but they are of little value in the prediction of probable results of cleaning a
range of coals by one specific process.
NOTE 6 Partition coefficients, écart probable (moyen) and imperfection are valuable for the purpose of prediction but do not give an
adequate indication of the accuracy of a given separating operation on a particular coal.
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ISO 923:2000(E)
Annex B
(normative)
Recommendations for standard methods of presenting coal cleaning test
data
B.1 Description of the tables
Two sets of tables are required (see clauses B.4 to B.7):
a) for three-product separation (cleaned coal, middlings and reject);
b) for two-product separation (cleaned coal and reject).
For convenience, an identical layout has been adopted for both sets of tables but, in those intended for use with
two-product separations, the columns that relate only to three-product separation have been left blank to avoid
confusion.
Each set of tables is presented in two ways.
a) Blank tables, to show the method of printing (see Form 1 and Form 3 in clauses B.4 and B.6, respectively).
b) Tables completed by filling in the figures relating to test results. For example, Form 2 and Form 4 shown in
clauses B.5 and B.7 give the results of a test using a Baum jig washer.
NOTE The example described in this annex was carried out prior to the publication of ISO 7936. The particle sizes used
therefore are not in accordance with those specified in that International Standard.
For the test described in this example, the washer was supplied with coal sized from 152 mm to 0 mm. The figures
used refer to the fraction sized between 12,7 mm and 0,5 mm. The fine material below 0,5 mm was removed from
the samples before carrying out float and sink tests, because this fine material presents difficulties in testing.
Moreover, the jig is not expected to clean material smaller than 0,5 mm.
For a full analysis of the test, tables similar to those given for the 12,7 mm to 0,5 mm size would be required for the
other sizes of the raw coal, in this instance 152 mm to 51 mm, 51 mm to 25,4 mm, and 25,4 mm to 12,7 mm. Such
tables would enable the performance on the different sizes to be compared. By adding together the results on the
four individual sizes, a further set of tables could be constructed giving cumulative data for the whole of the 152 mm
to 0,5 mm coal.
In this test, three products were made: cleaned coal, middlings and reject. The reject is the material removed by the
primary reject elevator and the middlings is the reject from the secondary reject elevator. The tables headed "three-
product separation" are built up from float and sink tests at various relative densities from 1,30 to 2,20 on samples
of each of these three products. Although intervals of 0,1 relative density have been used for the example, different
ranges and intervals may be required in other cases.
The figures in the tables headed "two-product separation" have been calculated from these same figures on the
assumption that the products from both elevators (i.e. the middlings and the reject) were combined so that there
were two products only: cleaned coal and a single reject.
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ISO 923:2000(E)
B.2 Expression of efficiency in the three-product separation
Three-product separation may be regarded as a combination of two distinct two-product separations (i.e. a low-
density cut and a high-density cut), whether these two stages are in fact carried out in different separating vessels
or in different parts of the same vessel.
The diagrams in Figure B.1 illustrate different combinations of the two stages.
Key
F Feed (reconstituted raw coal)
C Cleaned coal
R Reject
M Intermediate product (middlings)
Figure B.1
Diagrams 1 and 2 represent typical arrangements for a two-stage dense-medium separation, the only difference
being that the low-density cut comes first in diagram 1 and second in diagram 2, whereas diagram 3 represents a
normal three-product jig (or a three-product dense-medium separation). The middlings M may be collected as a
separate product, or recirculated, or otherwise dealt with, but provided that any recirculated middlings are included
in the reconstituted feed F, the argument is unaffected.
The efficiency of a three-product separation may be calculated in two different ways:
a) Method A, by regarding it as two distinct and individual separations, each with its own feed;
b) Method B, by regarding it as a single comprehensive separation, the feed for which is the reconstituted raw
coal.
To calculate the partition coefficients, the appropriate formulae for these two methods, for the combinations of plant
illustrated in the diagrams, are as follows:
For diagram 1
100 (MR� )
a) Method A: low-density cut
CM��R
100 R
high-density cut
CM��R
100 (MR� )
b) Method B: low-density cut
CM��R
100 M
high-density cut
CM��R
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ISO 923:2000(E)
For diagram 2
100 R
a) Method A: high-density cut
CM��R
100 M
low-density cut
CM�
100 R
b) Method B: high-density cut
CM��R
100 M
low-density cut
CM��R
For diagram 3
100 R
a) Method A: high-density cut
CM��R
100 M
low-density cut
CM�
100 R
b) Method B: high-density cut
CM��R
100 (MR� )
low-density cut
CM��R
Although for Method A the formulae are identical for diagrams 2 and 3, in the latter case there is no sharp dividing
line between the first and second cuts. The first (high-density) cut separates the reject R from the combination of
the cleaned coal C and middlings M, and it is this combination that becomes the feed to the second stage of the
separation.
Method A enables the efficiency of each of the two separations to be studied individually, because only the material
actually admitted to the separation is included in the calculation. This is of advantage when considering the
performance of each machine or stage in the separation process.
Method B does not show up so emphatically the actual performance of the second machine or stage, but by
referring each separation back to the reconstituted raw feed it facilitates comparisons of the efficiency of the whole
separation process in terms of the results on the original raw coal. (The sequence of operations included in this
complete process may include steps not shown in diagrams 1 to 3, for example crushing of the middlings and its
recirculation to the feed, which is common in jig washing and may also occur in dense-medium separation.)
It is essential, whenever the efficiency of a three-product separation is expressed (for example, in descriptions of
plant and efficiency statements and guarantees), that it be clearly stated which of these two bases has been used
for the calculation. To facilitate this, it is proposed that Method A be described as the equipment performance
basis, and Method B as the coal performance basis.
Tables B.1 to B.10 for the three-product separations are drawn up on the coal performance basis. When
calculations are made on the equipment performance basis, it is recommended that two-product tables be used
(one for each stage). It is possible, however, to deduce the results from the three-product table; thus, partition
coefficients for the second cut would be calculated on the equipment performance basis as follows:
a) for diagram 1 (see Figure B.1 in clause B.2), column (12) would be calculated from (7)/(9) instead of (7)/(10) in
Table B.7;
b) for diagrams 2 and 3 (see Figure B.1 in clause B.2), column (13) would be calculated from (6)/(8) instead of
(9)/(10) in Table B.7.
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ISO 923:2000(E)
B.3 Descriptions of the graphs (see annex C)
B.3.1 Introduction
To calculate the efficiency, the data required in clause B.4 (Tables B.1 to B.5) and clause B.6 (Tables B.11 to B.15)
should be represented in graphs. Graphs relating to the test results in clause B.5 (Tables B.6 to B.10) and in clause
B.7 (Tables B.16 to B.20) are shown in Figures C.1 to C.4. The graphs have been prepared from the data for three-
product separation; but the curves for the low-density cut apply to the two-product example.
Figure C.1 has been drawn to such a scale that 0,2 unit on the relative density axis equals 10 % on the partition-
coefficient axis. It is proposed to standardize this relation for drawing partition curves, when using (as in Figure C.1)
linear coordinates, but similar standard scales for the other curves are not considered to be practicable at present.
The curves can also be drawn using coordinates that are other than linear.
The construction and use of the graphs in Figures C.1 to C.4 are explained in B.3.2 to B.3.5.
B.3.2 Partition curves (three-product) (see Figure C.1)
The partition coefficients in columns (12) and (13) in Table B.7 are plotted against the mean of the relative densities
shown in Table B.7 for each fraction.
The curve on the right of Figure C.1 represents the high-density cut because it refers to the removal of the final reject.
The table columns from which the coefficients are extracted are shown on each curve.
The relative density at which the curves cross 50 % is by definition the partition density. Similarly, écart probable
(moyen) (Epm) is defined in terms of the relative densities d and d at which the curves cross 25 % and 75 %
25 75
respectively. The imperfection (I) is derived from these as shown.
B.3.3 Ash error and organic efficiency (see Figure C.2)
The curve in Figure C.2 shows the cumulative mass on the reconstituted feed plotted against the cumulative ash
percent, the figures being taken from columns (43) and (45) in Table B.10.
The point X represents the actual yield and ash for the high-density cut (total cleaned coal and middlings), and the
point Y represents those for the low-density cut (total cleaned coal).
Regarding point X.
� The actual ash is 5,61 % and the theoretical float and sink ash for the actual yield of 93,4 % as given by the
curve is 5,05 %. The ash error is the difference between these two ash percentages.
� The actual yield is 93,40 % at 5,61 % ash. The theoretical float and sink yield for 5,61 % ash is given by the
curve as 94,60 %. The organic efficiency is derived from the ratio of these two yields.
Similar considerations apply to point Y.
B.3.4 Correctly placed (and misplaced) material — High-density cut (see Figure C.3)
The two lower curves in Figure C.3 show the amounts of misplaced material in the reject (column 18 in Table B.8)
and the cleaned coal plus middlings product (column 17 in Table B.8), the fraction which in this example goes
forward for further treatment. The upper curve shows the sum or total of the misplaced material in these two
products combined (column 19 in Table B.8). The total amount (percentage) of correctly placed material (100
minus misplaced material) is read from the scale on the right-hand side of the graph.
The equal-errors cut-point (density) is the relative density at which the two lower curves intersect; in this example, this
density is 1,770. The partition density is 1,835.
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ISO 923:2000(E)
The relative densities of 1,770 and 1,835 correspond respectively to 96,6 % and 96,7 % for the amounts of correctly
placed material.
B.3.5 Correctly placed (and misplaced) material — Low-density cut (see Figure C.4)
The same considerations apply as for the high-density cut, the amounts of misplaced materials in each product
being plotted from columns (23) and (24) and the total from column (25) in Table B.8. The equal-errors cut-point
(density) and the partition densities are 1,400 and 1,505 and the amounts of correctly placed material 89,9 % and
91,0 % respectively.
The curves in Figures C.1 to C.4 have been drawn on the coal performance basis, all yields being expressed as a
percentage of the reconstituted raw coal. On the equipment performance basis, the washing operation being
regarded as two distinct two-product separations, the construction of the curves follows exactly the same method
as for any two-product separation and presents no difficulties. The curves that apply to the high-density cut
(Figure C.1: lower curve; Figure C.2: point X; Figure C.3: upper curve) are identical for both bases.
B.4 Form 1 — Tables for three-product separation
Table B.1 — Data required for calculation of efficiency of three/two-product separation
Reference: Date of test: Name of plant:
Test details Mass Summary results
(1) Single cut: Actual products
Size of coal analyzed, Size Total feed to (see note)
mm analyzed plant Cleaned coal
Reject
(1) High-density cut:
Size of feed to plant,
Cleaned coal + Middlings/Reject
t% t%
mm
(2) Low-density cut:
Cleaned coal/Middlings + Reject
Raw
Type of cleaning unit coal
treated
Products Separating Correctly
density placed
Rated capacity, t/h
material
Cleaned
%
coal
Middings (1) (2) (1) (2)
Seam(s) treated Partition
Reject
Equal errors
h Feed rate, t/h
b
Actual testing period
Epm
min
a
Basis of masses: Dry
h
a
Air dry
Total stoppages Imperfection
min
a
As received
Ash error
Net testing time
h
Organic
min
%%
efficiency
NOTE For a two-product separation, the products are named “cleaned coal” and “reject”, although the actual products may in fact be
cleaned coal and reject or cleaned coal and middlings or middlings and reject.
a
Cross out those that do NOT apply.
b
Epm: Écart probable (moyen).
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ISO 923:2000(E)
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Table B.2 — Distribution by mass of products and reconstituted feed
Cleaned Recon- Relative
Middlings
Analysis by mass Percentage of feed Partition coefficient
coal + stituted density
+ reject:
middlings: feed (nominal)
Relative
density
Cleaned Middlings Reject Cleaned Middlings Reject high- low-density
fractions
coal coal density cut cut
High-density Low-density
cut cut
%% % %
Percentage Percentage Percentage
...
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