The disclosure relates to the field of coal screening and sorting systems and processes, in particular to a process for upgrading lignite by collaborative optimization of drying and dry sorting.
Coal is the main energy source in China, where lignite totals about approximately 130.3 billion tons, accounting for 16% of the country's total coal reserves. In 2017, China's coal output was 3.52 billion tons, accounting for about 60.4% of the national energy consumption. Although the demand for coal resources is large, with the depletion of coal resources in the east and the large-scale development of high-rank coal, China has entered a period of low-rank coal resources development. The utilization of low-rank coal will become more and more important. However, lignite has a relatively high moisture content, with an average total moisture content of about 30%. It is difficult to meet the requirements of production and life in terms of calorific value, and the pollutants produced by lignite are several times those of high-rank coal. In addition, lignite is easy to weather and ignite spontaneously, which brings difficulties to long-distance transportation and long-term storage. Therefore, the large-scale upgrading of lignite resources is of great strategic significance for realizing the continuous supply of coal-based energy and ensuring the rapid and sustainable economic development in China.
Lignite features a low degree of coalification, a high moisture content, a high volatile content and a low calorific value, which determines that lignite must be upgraded through deashing and drying before it is used. Because lignite is easy to degrade in water, it is difficult to be upgraded by using a wet sorting process, which cannot achieve both deashing and drying and has complicated operation, high energy consumption and high production cost. As for deashing by dry sorting, it has strict requirements on the surface moisture of the raw coal. In addition, the existing single drying process of coal has problems such as high energy consumption, an unstable interface after drying, and easy re-adsorption of upgraded coal. It can only achieve partial water removal, and cannot achieve coal sorting.
Purpose: In order to overcome the shortcomings existing in the prior art, an objective of the disclosure is to provide a process for upgrading lignite by collaborative optimization of drying and sorting. The upgrading process features simple operation, high sorting efficiency, low energy consumption and low production cost.
Solution: In order to achieve the above objective, the disclosure adopts the following optimized technical solution. A process for upgrading lignite by collaborative optimization of drying and dry sorting, including: selecting, optimizing and combining appropriate drying and dry sorting processes based on a relationship between a calorific value of lignite and a moisture content and an ash content thereof as well as a production cost required by a production process, and implementing the dry sorting process first and then the drying process, specifically including:
The relational expression between the calorific value of lignite and the ash content and moisture content thereof is as follows:
Q
gr,d=23.34−0.26285Mt−0.21954Ad+0.16979Var−0.00147Vdaf2 (1)
In the equation, Qgr,d represents the calorific value of lignite, Mt represents a total moisture content of the coal, Ad represents the ash content of the coal, Var represents the ash content of an as-received basis, and Vdaf represents a volatile content of a dry ash-free basis.
The relational expression between the production cost (S) and the ash content (Ad) and moisture content (Mad) of the coal is as follows:
In the equation, HMA represents a tangent point between an iso-cost line and the calorific value, namely a lowest point of the production cost; S represents the production cost; Ad represents the ash content of the coal; Mad represents the moisture content; ω represents a proportion of moisture removed during the sorting process; γ represents a proportion of ash removed during the sorting process.
The lignite ash reduction pretreatment process is a process of first preliminarily reducing ash and then deeply drying: first feeding the lignite to X-ray dry sorting equipment, composite dry sorting equipment or fluidized-bed equipment for initial gangue removal to remove gangue partially, so as to reduce an energy loss in the lignite drying process; and allowing the lignite after the gangue removal to enter microwave, vibrating mixed-flow or fluidized-bed equipment for drying.
In the above solution, according to the quality of lignite, appropriate drying and dry sorting processes are selected, optimized and combined. Lignite has a high moisture content. Water mainly exists in free form in gaps between lignite particles and in large-diameter pores on the surface of lignite. The binding force of water is weak, and it is dominated by intermolecular forces. Such water is simple to remove and the required energy consumption is low. Therefore, the process of first dry sorting and then drying is selected to upgrade lignite. In the technical solution, before production, equation (1) is selected to pre-assess the calorific value of the coal, and equations (2) and (3) are combined for cost budgeting. Then, the degrees of deashing and drying are determined, so as to quantitatively control the production process. The water on the surface of lignite is easily affected by temperature, so after the coal enters the drying equipment, the free water on the surface of the lignite is quickly removed. This treatment meets the practical application requirements, improves the quality of lignite, and achieves the drying and ash reduction of the coal.
Advantages: By adopting the idea of integrated drying and dry sorting, the disclosure improves the quality of lignite. The disclosure meets the requirement for the surface moisture of the raw coal in the dry sorting operation, reduces the ash content of the coal, increases the calorific value of the coal and the output of clean coal, reduces the energy loss and production cost, and simplifies the process flow. The upgrading process features simple operation, high sorting efficiency, low energy consumption and low production cost, and realizes good economic and practical benefits.
The disclosure provides an optimized upgrading method, including: selecting, optimizing and combining appropriate drying and dry sorting processes based on a relationship between a calorific value of lignite and a moisture content and an ash content thereof as well as a production cost required by a production process, and implementing the dry sorting process first and then the drying process:
The relational expression between the calorific value of lignite and the ash content and moisture content thereof is as follows:
Q
gr,d=23.34−0.26285Mt−0.21954Ad+0.16979Var−0.00147Vdaf2 (1)
In the equation, Qgr,d represents the calorific value of lignite, Mt represents a total moisture content of the coal, Ad represents the ash content of the coal, Var represents the ash content of an as-received basis, and Vdaf represents a volatile content of a dry ash-free basis.
The relational expression between the production cost and the ash content and moisture content of the coal is as follows:
In the equation, HMA represents a tangent point between an iso-cost line and the calorific value, namely a lowest point of the production cost; S represents the production cost; Ad represents the ash content of the coal; Mad represents the moisture content; ω represents a proportion of moisture removed during the sorting process; γ represents a proportion of ash removed during the sorting process.
The lignite ash reduction pretreatment process is a process of first preliminarily reducing ash and then deeply drying: first feed the lignite to X-ray dry sorting equipment, composite dry sorting equipment or fluidized-bed equipment for initial gangue removal to remove gangue partially, so as to reduce an energy loss in the lignite drying process; and allow the lignite after the gangue removal to enter microwave, vibrating mixed-flow or fluidized-bed equipment for drying.
The disclosure is described in further detail below with reference to the accompanying drawings.
Step A: The final ash content and moisture content of lignite were determined by using two evaluation indicators, namely calorific value and production cost. Considering the high moisture content of lignite, the production process was determined as first preliminary gangue removal and then drying.
Step B: The lignite was fed to an elastic grading screen through a chute by a belt conveyor for deep dry grading. The mesh size of the elastic screen was 30 mm. The oversize lignite larger than 30 mm entered a crusher. The coal discharged after crushing and the undersize coal smaller than 30 mm filtered by the elastic grading screen entered X-ray dry sorting equipment, composite dry sorting equipment or fluidized-bed equipment for initial gangue removal. In this way, part of the gangue was removed, so as to meet the ash reduction requirement.
Step C: The undersize lignite smaller than 30 mm filtered by the elastic grading screen and the lignite crushed by the crusher selectively entered vibrating mixed-flow, microwave and fluidized-bed equipment for micro drying treatment. The surface moisture of the coal was removed, and the drying was stopped when an expected drying purpose was achieved.
Step D: After the micro ash reduction treatment, the lignite entered the microwave, vibrating mixed-flow or fluidized-bed equipment for drying, and after a certain period of drying treatment, a desired product was obtained.
Number | Date | Country | Kind |
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201810619868.8 | Jun 2018 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2019/090619 | 6/11/2019 | WO | 00 |