CN1103450C - Determination of float-and-sink composition of coal based on its ash content - Google Patents
Determination of float-and-sink composition of coal based on its ash content Download PDFInfo
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- CN1103450C CN1103450C CN97119149A CN97119149A CN1103450C CN 1103450 C CN1103450 C CN 1103450C CN 97119149 A CN97119149 A CN 97119149A CN 97119149 A CN97119149 A CN 97119149A CN 1103450 C CN1103450 C CN 1103450C
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Abstract
The present invention provides a method for determining the float-sink composition of coal according to the ash content of the coal, which replaces a method of a coal float-sink test. The method can fast determine the float-sink composition of the coal according to the ash content of the coal and historic float-sink test data. According to the large quantity of historic data of the float-sink test in the same mine field, a regression equation of the cumulative yield of the ash content of the raw coal and floating objects with the density steps of -1.4, -1.5, -1.6 and -1.8 and a quadratic regression equation in one unknown with the same density as the density of the elementary ash content are obtained. When the predication is carried out, the coal ash content is substituted into the regression equation to obtain the float cumulative yield of-1.4, -1.5, -1.6-1.8. The density equation of the elementary ash content is integrated to obtain the average ash content of each density step. So far, the determination of the float-sink composition of the coal is completed.
Description
Technical field:
The present invention relates to the method that a kind of ash content according to coal determines that drifting along of coal formed, this is a kind of method that replaces the coal float-and-sink analysis, the composition that drifts along that this method can be determined coal fast according to the ash content and the historical float-and-sink analysis data of coal.
Background technology:
As everyone knows, must carry out the composition that drifts along that float-and-sink analysis could be understood coal at present, float-and-sink analysis need expend great amount of manpower and material resources, and needs just can finish at least in several hours, can not adapt to the needs of automatic control; Design or often lack the float-and-sink analysis data when predicting, unconditionally take coal sample to carry out float-and-sink analysis again.But the ash rate of raw coal is easier to obtain.
Summary of the invention:
The objective of the invention is to propose a kind of method of drifting along and forming that a kind of ash content according to coal is determined coal that relates to, this is a kind of method that replaces the coal float-and-sink analysis, and this method can be determined the composition that drifts along of coal fast according to the ash content of coal and historical float-and-sink analysis data.
The present invention is the composition that drifts along of determining coal according to the ash content of coal, and realizes as follows:
The historical summary of coal float-and-sink analysis of collecting identical mining area is more than eight parts;
Determine the floating accumulative total productive rate of-1.4 ,-1.5 ,-1.6 ,-1.8 densimetric fractions and the regression equation of coal ash relation with the simple linear regression analysis method:
R
i=A
i+B
iASH …… (1)
In the formula: i=1.4,1.5,1.6,1.8; R
iBe floating thing accumulative total productive rate; ASH is a coal ash; A
i, B
iBe parameter, try to achieve with regression analysis by historical summary.
Try to achieve the mathematical model that cumulative float curve is density-floating thing accumulative total productive rate relation with the nonlinear fitting method:
R=f(X) …… (2)
The floating thing accumulative total of R-productive rate, X-density.
Determine the relation of elementary ash λ and raw coal density with the One-place 2-th Order regression analysis:
λ=C+DX+EX
2 …… (2)
In the formula: λ is an elementary ash; X is a density; C, D, E is a parameter, is tried to achieve by regretional analysis side by historical summary.
Try to achieve the average ash content of each densimetric fraction with integral method:
D1, d2 are the bound of density.
So far, finish determining that coal drifts along and forms.
The present invention has following advantage compared with the prior art: in the time can't testing, can determine the composition that drifts along of coal according to historical summary, for design provides foundation with controlling automatically.Do not test, obtain raw coal float-and-sink analysis data fast, use manpower and material resources sparingly.
Embodiment:
Use that the present invention forms the density of 75 fens data of six factories of China and coal ash concern that result of study is as shown in table 1.As shown in Table 1, the related coefficient of-1.4 densimetric fraction content and coal ash is 0.88 ,-1.5, and-1.6 and-1.8 related coefficient is 0.98-0.99.Table 2 is six factory's elementary ashes-density regretional analysis result, and the facies relationship number average is greater than 0.99.Table 3 is that accuracy of predicting is gratifying to Xingtai coal preparation plant and the prosperous village coal preparation plant's measured result and the contrast that predicts the outcome.
Table 1 coal ash-floating thing accumulative total productive rate regretional analysis result
Density | The data umber | The regretional analysis result | ||
A | B | Related coefficient | ||
-1.4 | 75 | 87.6583 | -1.08637 | 0.88 |
-1.5 | 75 | 102.9435 | -1.26965 | 0.98 |
-1.6 | 75 | 107.25422 | -1.27056 | 0.99 |
-1.8 | 75 | 110.16179 | -1.22630 | 0.99 |
Six factory's elementary ashes of table 2-density regretional analysis result
Factory's name | The data umber | The regretional analysis result | |||
C | D | E | Related coefficient | ||
Dragon and phoenix | 16 | -289.3714 | 332.59464 | -81.05357 | 0.999 |
Big village | 12 | -152.3331 | 141.06643 | -15.96428 | 0.997 |
Xingtai | 16 | -218.7614 | 241.12143 | -53.35714 | 0.998 |
The Huaibei | 9 | -226.2877 | 241.84179 | -50.41071 | 0.999 |
East is huge | 11 | -59.71514 | 17.217143 | 24.714286 | 0.994 |
The prosperous village | 12 | -224.6771 | 241.51607 | -50.55357 | 0.995 |
Table 3 measured result and the contrast that predicts the outcome
Factory's name | Density | Measured result | Predict the outcome | ||
Productive rate % | Ash content % | Productive rate % | Ash content % | ||
Xingtai coal preparation plant | -1.4 | 57.76 | 6.57 | 57.88 | 6.13 |
1.4-1.5 | 9.12 | 15.77 | 8.99 | 15.54 | |
1.5-1.6 | 3.76 | 23.56 | 3.40 | 23.13 | |
1.6-1.8 | 3.10 | 35.10 | 3.07 | 34.91 | |
+1.8 | 26.26 | 80.08 | 26.66 | 80.33 | |
Add up to | 100.00 | 28.22 | 100.00 | 28.22 | |
Prosperity village coal preparation plant | -1.4 | 70.65 | 6.41 | 70.81 | 6.69 |
1.4-1.5 | 11.07 | 16.78 | 11.26 | 16.69 | |
1.5-1.6 | 3.94 | 25.79 | 3.58 | 25.36 | |
1.6-1.8 | 2.98 | 39.39 | 3.23 | 38.92 | |
+1.8 | 11.36 | 86.25 | 11.12 | 86.32 | |
Add up to | 100.00 | 18.38 | 100.00 | 18.38 |
Above-mentioned result of study shows, the present invention is according to the historical summary of coal float-and-sink analysis, is feasible according to the ash content prediction coal of the coal method of forming of drifting along, and its precision of prediction is higher.Do not satisfying the requirements when carrying out float-and-sink analysis, can determine the composition that drifts along of coal fast, general Practical significance is being arranged.
Claims (1)
1, a kind of ash content according to coal is determined the method for drifting along and forming of coal, and concrete grammar is:
(1) determine the floating thing accumulative total productive rate of-1.4 ,-1.5 ,-1.6 ,-1.8 densimetric fractions and the regression equation of coal ash relation by historical summary with the simple linear regression analysis method:
R
i=A
i+B
iX …… (1)
In the formula: i=1.4,1.5,1.6,1.8; R
iBe floating thing accumulative total productive rate; X is a coal ash; A
i, B
iBe parameter;
(2) try to achieve the One-place 2-th Order regression equation of elementary ash and density according to historical summary,
λ=C+DX+EX
2 …… (2)
In the formula: λ is an elementary ash; X is a density; C, D, E is a parameter, is tried to achieve by regression analysis by historical summary;
When (3) predicting, when ash content of coal substitution formula (1) is tried to achieve this ash content ,-1.4 ,-1.5 ,-1.6 and-1.8 floating things accumulative total productive rates; To formula (2) integration, try to achieve the average ash content of each densimetric fraction;
So far, when finishing a certain coal ash, what coal drifted along and forms determines.
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CN97119149A CN1103450C (en) | 1997-10-15 | 1997-10-15 | Determination of float-and-sink composition of coal based on its ash content |
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CN97119149A CN1103450C (en) | 1997-10-15 | 1997-10-15 | Determination of float-and-sink composition of coal based on its ash content |
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CN1214452A CN1214452A (en) | 1999-04-21 |
CN1103450C true CN1103450C (en) | 2003-03-19 |
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Families Citing this family (6)
Publication number | Priority date | Publication date | Assignee | Title |
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CA2787667C (en) * | 2009-11-18 | 2018-02-27 | Tata Steel Limited | Float-sink method and apparatus to determine beneficiation prospects of minerals |
CN102836774B (en) * | 2012-09-04 | 2015-02-25 | 永城煤电控股集团有限公司 | Coal floating and sinking device and method |
CN103472204B (en) * | 2013-10-08 | 2015-04-01 | 天地(唐山)矿业科技有限公司 | Method for detecting ash content of floatation products |
CN105547917A (en) * | 2016-02-22 | 2016-05-04 | 天地(唐山)矿业科技有限公司 | Automatic detection method for coal product ash content |
CN106417007A (en) * | 2016-10-11 | 2017-02-22 | 贵州省油菜研究所 | Methods for determining and screening high-oil-content varieties of hybrid Brassica napus |
CN106680140B (en) * | 2017-01-10 | 2019-08-13 | 中国矿业大学 | A kind of coal float-sink test device and method |
Citations (1)
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CN1087174A (en) * | 1992-11-19 | 1994-05-25 | 湖南省建筑材料工业协会 | A kind of material contains the rapid assay methods of coal amount |
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CN1087174A (en) * | 1992-11-19 | 1994-05-25 | 湖南省建筑材料工业协会 | A kind of material contains the rapid assay methods of coal amount |
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