DD279799A3 - METHOD AND ARRANGEMENT FOR CONTROLLING MULTIPLE COAL APPLICATORS ACCESSING A CENTRALIZED TRANSPORT SYSTEM - Google Patents

Abstract

Method and arrangement for controlling a plurality of coal feed devices conveying feed conveyors onto a central transport system for supplying a coal processing plant. The object is to control the coal feeding facilities so that the coal processing plant is a quantity-dependent characteristic with a narrow tolerance width supplied. This is achieved according to the invention by simultaneously measuring the mass flow rate, the ash content and / or the calorific value and / or the water content and / or the bulk density of the coal in the real-time operation of the individual coal feeders. From the individual measured values, the total amount and the mean value are determined Quality Characteristics of the Central Transport Facility are calculated and compared with the actual quantity and quality characteristics required for the coal processing plant, from the comparison calculated a quantity and quality appropriate separation or combination of Kohlefoerderstroeme and by corresponding change in the delivery rates of the individual coal feeding facilities based on the setpoints for the Total quality and average quality is controlled, the quality feature of the ash content and / or the water content and / or the calorific value and / or the Schuettdichte the coal and the mass flow vorzugsw is formed from the radiometrically measured surface mass, the Schuettgutquerschnitt and the velocity of the coal stream. figure

Description

For this 1 page drawing

Field of application of the invention

The invention relates to a method and an arrangement for controlling in-ear, via conveyor belts on a central transport system promoting coal feeding facilities for supplying a coal processing plant.

Characteristic of the known state of the art

Large customers of lignite, such as coal processing plants for the production of electric power, district heating, briquette or coke each require a production process adapted specific fuel quality. So requires z. As the briquetting and coking the use of coal with low ash contents. High ash contents also endanger the fire control in the steam generators of the large power plants. The declaration of the coal quality is usually done in open pit mining by extraction and analysis of coal samples, while the delivered quantity is mainly determined by the customer by weighing. Both types of determination occur at different locations and usually with a large time difference. On the other hand, complicated mining conditions lead to greater fluctuations in coal quality, which can no longer be detected by individual sampling. In order to stabilize the coal quality, it is therefore necessary to superimpose various types of coal already in the raw state in terms of quantity and quality. In order to achieve the desired mixed coal quality in the subsequent processing of the coal. It was proposed to declare the quality characteristics of a trainload by means of sampling and radiometric rapid determination and to tilt trainloads with different quality characteristics in layers or selectively on coal storage areas. However, the desired average coal quality could not be achieved because the uniform mehischichtige Abhaldung from the accumulated by the storage bulk profiles was not possible.

Furthermore, it has been proposed to realize the union of crude lignite discharge streams with two conveyor belts whose mass flow rates are fixed preset on the basis of average quality characteristics. Practical experiments in a lignite-fired power plant have shown that the average values used for a quantity presetting, for. As the calorific values, have a large range of variation, so that the tolerance of the desired Sollheizwertes the mixture could not be met.

There are known radiometric belt weighers for the determination of the mass flow rate of bulk materials and radiometric ash meter for determining the content of the conveyor belt.

With these known solutions, the quantity and quality can only be detected individually. An influence on the coal flow is not possible.

Object of the invention

The aim of the invention is to ensure a continuous supply of a coal processing plant.

Explanation of the essence of the invention

The invention has for its object to control via conveyor belts on a central transport system Kohletiufgabeeinrichtungen for supplying a coal processing plant so that the coal processing plant a predetermined quality characteristic with a small tolerance width is supplied depending on the quantity. This is inventively achieved in that at the same time the mass flow rate, the ash content and / or the calorific value and / or the water content and / or the bulk density of the coal are measured in real-time operation of the individual coal flow rates from the individual measured values, the total amount and the middle Quality Characteristics of the Central Transport Facility are calculated and compared with the instantaneous quantity and quality characteristics required for the coal processing plant, calculated from the comparison oine volume and quality appropriate separation or merger of the coal flow rates and by appropriate change in the flow rates of the individual coal feed facilities based on the setpoints for the Total quality and average quality is controlled, the quality feature of the ash content and / or the water content and / or the calorific value and / or the bulk density of the coal and the mass flow vorzugsw is formed from the radiometrically measured basis weight, the Schüttgutqueischnitt and the speed of the coal stream.

The quantity and quality characteristics of coal and their time course are evaluated by frequency distributions. Furthermore, at the rates of coal production with hard gamma radiation, the surface masses and the bulk density are continuously measured, with soft gamma radiation the radiometric mass attenuation coefficient and with neutron, microwave or infrared radiation the water content.

In addition, according to the invention the mass flow rate of the coal feeding devices is selectively controlled by controlling the speed, the feed, the engagement depth and the angle of attack of clearing wheels, bucket chains, paddle wheels, rotary valves or valves.

The arrangement for carrying out the method is designed such that under each upper strand of the conveyor belts a gamma emitter with a plurality of radiation sources and in the beam path above the Fördergutschicht a detector, laterally next to the upper strand another Gamma «trahler and in its Sirahlengang on the other side of the upper strand a detector and at the top strand far ahead combined one.? Emitter-detector unit are arranged, wherein cie detectors and the emitter-detector unit are connected via measuring lines to a central evaluation unit, the evaluation unit is coupled via a serial output to a central computer system, from the evaluation control lines to the Kohleaufgabe- or Dosing devices are guided and optionally a terminal is coupled to the evaluation unit. In a further embodiment, the radiation sources of the gamma emitter are arranged below the upper strand in stacked construction next to each other or one above the other.

The detector above the Fördergutschicht is arranged at a safe distance above the Fördergutschicht. The gamma emitter is arranged next to the upper strand at a constant bulk material cross section. The emitter-detector unit is preferably arranged at a location of the upper strand with a constant bulk profile or at a location of Fördergutschicht with variable bulk profile.

embodiment

The invention will be explained in more detail below using an exemplary embodiment. The accompanying drawing shows the arrangement for the control in a schematic representation.

At the individual coal conveying streams, a gamma emitter 3 with a plurality of radiation sources in stacked construction is arranged side by side or one above the other under each upper strand 1 of the conveyor belts with the conveying material layer 2. In the beam path 5 of the gamma rays 3, a detector 4 is arranged with a safety distance A above the Fördergutschicht 2. The detector 4 is a two or more channel scintillation quotient spectrometer with a measuring range of 15 keV to 1.5 MeV. Laterally next to the upper strand 1, a further gamma emitter 6 are arranged on a constant bulk material cross-section B and in the beam path 3 on the other side of the upper strand 1 a detector 7 is arranged. The gamma emitter 6 is designed to have a quantum energy equal to or greater than 660 keV. At the upper strand 1, a combined Stiahler detector unit 9 or 10 is further arranged. The emitter-detector unit 9 is arranged at a location of the upper strand 1 with a constant bulk profile, the emitter-detector unit 10 at a location of Fördergutschicht 2 with variable bulk profile laterally over or parallel to the detector 4. The detectors 4; 7 and the emitter-detector unit 9 and 10 are connected via measuring lines 11 to a central evaluation unit 12, which is coupled via a serial output 14 with a central Rechenanlag = s. From the evaluation unit 12 control lines 15 to the Kohleaufgabe- or Dosiereinrichtungan 16, such as clearing wheels, assigners, bucket chains, paddle wheels, butterfly valves or Rotary valves guided. To the evaluation unit 12, a terminal 13 is optionally coupled.

In order to control the coal feed devices which convey via conveyor belts to a central transport system, the mass throughput, the ash content and / or the calorific value and / or the water content and / or the bulk density of the coal are measured simultaneously in real-time operation at the individual coal feed streams. For this purpose, the mass attenuation coefficient and the basis weight are measured with the gamma emitter 3 and the detector 4 and from the ash content, the calorific value and the individual components such as iron, sulfur or z. B. also determined bone and salinity of fats. The bulk density is determined from the measured quotient "basis weight by bulk material cross-section" with the aid of the detector 7. The total water content is determined with the radiator-detector unit 9 or 10. From the individual measured values, the total quantity and the mean quality characteristic of the central transport system are calculated and From the comparison, a quantitative and quality-appropriate separation or combination of the coal flow rates is calculated and by correspondingly changing the flow rates of the individual coal feeder or metering devices 16 based on the setpoint values for the total amount In the evaluation unit 12, the density signal from the detector 7 can be coupled to the signal from the emitter-detector unit 9 or 10 for density correction, and the signal from the detector 4 (area m se or Schütthöhenschwankung) with the signal from the emitter-detector unit 10 for correcting changes in distance to Fördergutschicht 2 are coupled. A further coupling can take place between the density signal from the detector 7 and the measurement value formation from the detector 4 for the approximate determination of the linear attenuation coefficient and for required limit value fluctuations. The quality characteristic is formed from the ash content and / or the water content and / or the calorific value and / or the bulk density of the coal. The mass flow rate is preferably formed from the surface mass measured by radiometry, the bulk material cross section and the velocity of the coal stream. The quantity and quality characteristics of coal and their time course are evaluated by frequency distributions.

The basis weight and bulk density are measured with hard gamma radiation, the radiometric mass attenuation coefficient with soft gamma radiation and the water content with neutron, microwave or infrared radiation.

The mass flow rate of the Kohleaufgabe- or metering device 16 is optionally controlled by controlling the speed, the feed, the engagement depth and the angle of attack of the clearing wheels, bucket chains, paddle wheels, rotary valves or butterfly valves.

While the previous radiometric measuring devices are only applicable to a specific type of coal with precisely attributable water contents, the new process can be used to measure different types of coal with strongly fluctuating water contents while at the same time reducing fault tolerance. For example, the fault tolerance in the continuous radiometric determination of the calorific value of raw lignite from ± 100 kcal / kg to ± 60 kcal / kg and the ash content of ± 3.8% rel. to ± 2.5% rel. be reduced.

With the help of density measurement foreign body deposits in the coal stream can be localized and with the help of the 2-fold y-transmission the Fremdkörperart determinable. Furthermore, with the product of density x mass attenuation coefficient coal and spoilage shares can be clearly distinguished and selectively maintained. The large measuring range and the multichannel spectrometric analysis of the spectra allow the determination of individual material components of a bulk material.

Claims (8)

1. A method for controlling a plurality of conveyor belts on a central transport system promoting coal feeding facilities for supplying a coal processing plant in which the properties of the individual coal flow rates radiometrically after a two-Gamrr. _; Radiation detected, converted into control signals and fed to a central evaluation unit, characterized in that at the same time the quality feature by absorption of soft gamma radiation in Meßgut by means of two linear Bewortunrjsfaktoren from the substance-specific mass attenuation coefficient of the 60-keV quantum radiation and the mass flow rate by absorption harder Gamma radiation in the material to be measured is determined from the radiometric calculated basis weight with the aid of evaluation factors for the bulk material cross section and bulk material velocity in real-time operation, a comparison of the actual values with a predefined setpoint for the total quantity and average quality and, in the event of a deviation, separation according to quantity and quality or combination of coal flow rates calculated and by a corresponding change in the flow rates of each coal flow in real time operation is made. 2. The method according to claim 1, characterized in that the quality feature au-; a surface mass measurement at constant bulk width is determined in a short time. 3. The method according to claim 1, characterized in that the quality feature is determined from a surface mass measurement at variable bed height in the short time cycle. 4. Arrangement for carrying out the method according to claim 1 to 3, characterized in that under each upper strand {1) of the conveyor belts, a gamma emitter (3) with a plurality of radiation sources and in the beam path (5) over the Fördergutschicht (2) a detector (4 ), laterally next to the upper strand (1) a further gamma emitter (5) and in the beam path (8) on the other side of the upper strand (1) a detector (7) and the upper strand (1) further eint combined emitter-detector egg The detectors (4, 7) and the emitter-detector unit (9, 10) are connected to the central evaluation unit (12) via measuring lines (11), the evaluation unit (12 ) is coupled via a serial output (14) with a central computer system, from the evaluation unit (12) control lines (15) to the coal feeding or metering devices (16) are guided and to the evaluation unit (12) coupled to a terminal (13) is. 5. Arrangement according to claim 4, characterized in that the radiation sources of the gamma emitter (3) under the upper strand (1) are stacked one above the other. 6. Arrangement according to claim 4, characterized in that the gamma emitter (6) next to the upper run (1) at a constant Schüttgutquerschi suffered (8) is arranged. 7. Arrangement according to claim 4, characterized in that the emitter-detector unit (9) is arranged at a position of the upper strand (1) with a constant bulk profile 8. Arrangement according to claim 4, characterized in that the emitter-detector unit ("O) is arranged at one point of Fördergutschicht (2) with variable bulk profile.