DD219290A1 - PROCESS FOR CARRIER DETERMINATION OF COAL - Google Patents

Abstract

The invention relates to a method for the radiometric determination of the ash content of coal with fluctuating composition of the combustible substance or of the secondary rock fraction by combining beta radiation and X-ray backscatter measurements. The intensities of the incident beta and X-ray radiation are adjusted (by selecting the sources, by means of diaphragms or absorbers) that the summation signal obtained by joint detection of the backscattered radiation as far as possible depends only on the ash content. Malfunctions due to fluctuating levels of iron, calcium and light elements are eliminated or greatly reduced. The required intensities of the incident radiations are found by first measuring separately the rates for both backscattered radiation types and then comparing them against each other.

Description

Method for the radiometric determination of the ash content of coal

Field of application of the invention , '

The invention relates to a method for the radiometric determination of the ash content of coal with fluctuating composition of both the light components (C, hydrocarbons, water) and the heavy components (ash: SiO ₂ , Al ₂ CU, Fe ₂ Cu, CaO) on the basis of measurements of beta radiation or X-ray ray backscatter. It is also suitable for determining the content of a major component in a multi-species system with a fluctuating matrix composition.

Characteristic of the known technical solutions

To determine the content of dual-substance systems, in particular for the determination of ash content or calorific value determination on coal, measurements of beta-radiation backscatter are widely used. The count rate of the backscattered beta particles is a puncture of the effective atomic number "Z" of the overall system:

Z = C ^ j Z ^ + CpZp

where c. the mass fractions and Z _{1 are} the atomic numbers of the constituents contained in the sample. In the case of ¹ coal is assumed that it can be considered as a two-component system, One component, the light components of coal (C, hydrocarbons, water) with the effective atomic number Z ₁ and the mass fraction c, the second component, the heavy

Ingredients (ash: SiO.sub.p, .A.sub.10O.sub.10,... CaO...) With the effective atomic number Z ,, then, are approximately:

Atomic number Ζ, _Λ and the mass fraction c,. For the ash-shark

A ² A - ^Z l

In practice, however, there are certain fluctuations in the composition of the coal, light and heavy coal components, which lead to fluctuating Z and Z, and thus to ash content measurement errors. Fluctuating levels of Fe ₀ O and CaO are particularly pronounced. .

In order to increase the beta radiation backscatter measurements of backscattered quantum radiation with primary energies between 7 keV and 100 keV are used. The backscatter rate in this case is a function of the effective mass attenuation coefficient / u:

/ U = C ₁₇ U _{1 +} c _{2 /} u ₂

or / u = Ca / U, + C ₁₇ U ₁ in the case of coal,

/. & / Ά Jl / Jm '

where c ... again the mass parts and , \ x. the mass attenuation coefficients of the elements contained in the sample mean. The mass attenuation coefficient / U, in turn, is a function atomic number Z :,,: -...

The exponent η is dependent on the primary energy between 0 and 4. These methods are therefore very sensitive to changes in the content of heavy constituents in the sample, ie in particular of iron and calcium in the coal In measurements of the ash content (ie especially of SiOp and AIpO.,), the content of Fe "OV and CaO must therefore be kept absolutely constant in the combustible matter of the coal and in constant proportions in the ash.

significant errors occur.

A method is known in which disturbances due to fluctuating iron contents are eliminated by registering the characteristic fluorescence radiation of the iron with the same detector in addition to the backscattered X-ray radiation. As the iron content increases, the increasing intensity of the characteristic x-ray radiation of the iron compensates for the decrease in the backscatter rate. Fine-tuning is done with a filter between the sample and the detector (Rhodes, J, R., et al., Radioisotope Instruments in Industry and Geophysics (Proc. Symp. Warsaw, 1965) 1, IAEA, Vienna (1966) 447; Cammack, .P ., Balint, Α., AIMS Annual Meeting, Las Vegas Nevada 1976, Preprint Ho. 76-F-24). However, fluctuations in the calcium content remain full and fluctuations in the composition of the light ivia tris partly as a disturbing effect. , ,

Finally, there is a method that consists in the excitation of the sample with X-rays and measurement of both the backscattered and the characteristic X-rays of iron and calcium in separate channels and the computational linkage of the measured values .. However, this requires a relatively large amount of equipment , '

Object of the invention

The object of the invention is to eliminate or reduce the effects of fluctuating compositions of the combustible substance or the minor rock fraction in the radiometric ash content determination of coal by means of beta or X-ray backscatter. '

Explanation of the essence of the invention

The invention has for its object to provide a method based on the beta or X-ray backscatter, in which the disturbing influences by fluctuating composition

the combustible substance or the Hebengesteinanteils eliminated or reduced. '.

The inventive method consists in the combination of beta and X-ray backscatter measurements and is characterized in that the backscattered radiation are detected together, the intensities of the primary radiation is adjusted so that the sum signal obtained as possible, depends only on the ash content - largely independent of the fluctuations in the composition of both the combustible (C, hydrocarbons) and the ashes (SiO ₂ , Al ₂ Oo, Fe ₂ Oo, GaO). The required intensities of the primary radiations are found by first counting the counts of the backscattered radiation Each type of radiation should be measured separately and then compared against each other. The adjustment is made in such a way that, despite changes in the content of heavy elements, the total counting rate remains constant (or nearly constant), since with increasing concentration of the heavy elements the backscattering rate of the beta radiation increases but the X-radiation decreases. When increasing z. B .. the iron content in the sample increases

    ι »....

counting rate due to the backscatter while the count rate is decreasing due to the backscatter of the X-ray. When changing the concentration of several components in the sample (iron, calcium, light elements), an empirical adjustment must be made so that the smallest scatter of the measured values is achieved. ,

The intensities of the primary radiation can be adjusted by appropriate choice of the source strengths and / or by means of diaphragms and / or absorbers. The energies of both types of radiation are chosen so that both radiations achieve approximately equal penetration depths into the sample. So z. For example, for the beta radiation for Sr-9O / Y-9O (2 Ie?), The penetration depth? X is about 20 % of the maximum range, ie. h, 200 mg-cm. This corresponds quite well to the depth of field $ χ of an X-ray of 15 keV (for a typical coal composition). Suitable beta radiation sources include Sr-9Q / Y-9O or Tl-204, as X-ray.

sources of radiation u. a. Pu-233 (E '= 15 keV) or' CD-109 (2 22 keV). The term X-ray radiation is used here only in the sense of characterizing an energy range, that is to say independently of the origin of the radiation.

In contrast to the known methods, which are based on the combination of eggununspezifischen and one or more element-specific measuring sections, the proposed method works with the combination of two elementunspezifischer Meßstrecken so that the interference of several components can be reduced.

The apparatus for carrying out the method consists of a respective beta and X-ray radiation source, a detector and the required counting and evaluation units, wherein the sources are arranged geometrically so that .beide backscattered types of radiation are detected with the single detector. Triggering tubes or ionization chambers (with suitable gas precipitation, eg B, xenon) can be used as detectors if an absorber of suitable thickness is placed in front of the detector to suppress the characteristic X-rays of heavy elements. But there are also energy dispersive detectors in embossing, z. B. Proportionalzählrohre (preferably with xenon filling), scintillation detectors with Berylliumeintrittsfenster or semiconductor detectors, wherein the characteristic X-radiation of the interfering elements is suppressed by an electronic threshold and / or by absorber.

The advantages of the invention are that disturbing influences are eliminated or greatly reduced by fluctuating composition of the ash or partly also by fluctuating composition of the combustible (C and hydrocarbons) of the coal. Furthermore, a partial elimination of the influence of Wassergehaltsschwanlcungen on the measurements reached. A further advantage is the fact that already existing measuring instruments based on beta-radiation backscattering for the content of the sbe mood can be retrofitted with an X-ray source as well as with - balancing filters and absorbers.

Implementation example .

FIG. 1 shows the block diagram of an arrangement for conducting and carrying out the method according to the invention, FIG. 2 shows the dependence of the count rate on iron content.

The arrangement consists of a beta radiation source 1 (Sr-90 / Y-9O), an X-radiation source 2 (Pu-238)., A detector 3, a S trhlungs casting machine 4, a ca display device 5 (printer, pen), a filter 6 in front of the detector 3 and .je a filter 7 and 8 in front of the Sirahlungsquellen. The arrangement is used to determine the ash content of lignite> 9 with fluctuating composition of the combustible constituents, or the ash in the coal. The activities (source strengths) of the two radiation sources 1 and 2 are selected such that the pulse counters registered by the detector 3 are in the range of the permissible pulse load capacity of the detector (about 1000 s -1). The filter β in front of the detector 3 is made of aluminum; it serves to absorb the characteristic X-ray radiation of the iron contained in the coal 9, which is excited by the Pu radiation. , '..

In order to eliminate the interfering influence of iron on the measurement result, an adjustment is first performed to determine the appropriate swelling strengths and filter thicknesses. For this purpose, a set of coal samples with increasing iron contents (from 1 to 10 % Fe, -, 0 " ) is prepared using starting coals with two different ash contents (eg A = 10 % and A ₂ '= 30 %) . These samples are measured individually with each source 1 or 2, ie, the count rates are determined as a function of the iron content and plotted (Figure 2) .The beta backscatter rate I increases with increasing iron content while the X-ray backscatter rate I ^ decreases Graphs of both dependencies and their sum (I, + I_) provides information on the measures required to minimize the dependence of the cumulative curve on the iron content Beta radiation control brought in, at

.... , , '. "'7 ..

If the X-ray backscatter rate I, "a copper absorber 8 also has a suitable thickness, before the X-ray source source, this procedure is continued until the sum curve I, + I in the iron content range of interest (of, for example, 2 to 4% Pe" O ^ in the coal) has sufficient independence from iron content. (Similar results can also be obtained by using apertures before the sources.) This procedure is done for at least two extreme ash levels in the ash content range of interest; For both ash contents, an independence of the total counting rate from the iron content must be achieved within the desired accuracy. This calibration is followed by the calibration of the measuring arrangement, ie. h., the determination of the dependence of the output signal on the ash content, on. ,.

The filter 6 in front of the detector 3 serves once for the absorption of the characteristic X-ray radiation and secondly for influencing the course of the beta backscatter curve.

Claims (3)

Claim of invention , 1. A method for determining the ash content of coal of a fluctuating · composition · both the light (C, hydrocarbons, water) and the heavy components (SiOp, AIpO-, FepO-3, CaO ·. *), Consisting of the combination of Bet _s a- and X-ray backscatter measurements, characterized in that the intensities of the primary radiation adjusted so v / earth, that the obtained by joint detection of both backscattered radiation types summation signal depends as possible only on the ash content and is influenced as little as possible by said fluctuations. 2. The method according to item 1, characterized in that the. Intensities of the primary radiation can be adjusted by selecting the source strengths or by means of aperture or by means of absorber. , , , ^: 3. The method according to item 1, characterized in that the energies of the two types of radiation are chosen so that their penetration depths in the sample material approximately , are the same. For this 1 page drawings