RU2209682C1 - Method for integrated processing of municipal solid domestic waste - Google Patents

Abstract

FIELD: waste disposal. SUBSTANCE: integrated method comprises sorting of waste and thermal and biothermal treatment of sorting products. Wastes of residential and nonresidential sectors are sorted separately to obtain valuable components, semifinished products, and tailing garbage. Residential sector waste is consecutively subjected to: magnetic separation to recover ferrous metals into magnetic fraction; separation of nonmagnetic fraction including fibrous and film components; primary riddling of separation tailings to give oversize and undersize products; air separation of undersize product to give light and heavy fractions; magnetic separation of heavy fraction to recover residual ferrous metals electrodynamic separation of nonmagnetic fraction to recover nonferrous metals; secondary riddling of electrodynamic separation tailings thereby obtaining oversize and undersize products. EFFECT: increased degree of material and energetic reuse of waste and increased efficiency of processing operations. 5 cl, 1 dwg, 4 tbl

Description

 The invention relates to the field of processing municipal solid household waste (MSW) and can be used in installations for their integrated processing and enrichment in cities of the Russian Federation.

 At present, in Russia, about 99% of the generated solid waste mass is being disposed of. At the same time, in Europe, by 2010, the rejection of the landfill for solid waste is planned due to their involvement in industrial processing. It is obvious that the same path, only more extended in time, has to go and Russia. The difficult economic situation in the country necessitates the development of methods for the phased solution of the problem of solid waste based on their involvement in industrial processing with minimal costs, while addressing resource conservation and environmental safety.

 A known method for sorting and processing urban solid waste, including separate waste disposal from the residential and non-residential sector of the city, manual and mechanized sorting of waste from the non-residential sector and compaction of tailings together with the waste from the residential sector of the city (O.P. Petrukov, V.Yu. Babkin, L . I. Shubov. Patent for invention 2164447, priority from 06.15.2000).

This method has two main disadvantages:
- there is no separate sorting of waste from the residential and non-residential sectors of the city, which does not ensure the integrated use of solid waste as technogenic raw materials;
- recycling by the method of compaction of tailings for sorting waste from the non-residential sector of the city together with the waste from the residential sector of the city does not solve the problems of material and energy waste disposal, neutralization and reduction of the amount of waste sent to landfill.

 The closest in technical essence and the achieved result is the integrated processing of solid waste, which provides for the preliminary sorting of waste with the release of valuable components, intermediate products (enriched fractions) and tailings, followed by the processing of intermediate products by thermal and biothermal methods (Shubov L.Ya., Zalepukhin R.V. The concept of industrial processing of municipal solid waste: the need for creation and the principles of construction. St. Petersburg, in the collection "New in the ecology and life safety". Report on III All-Russian Scientific and Practical Conference with International Participation. 1998, p. 48-59).

The main disadvantages of the known method of processing the entire mass of solid waste generated, without their separation into the residential and non-residential sector:
- there is no separate sorting of waste from the residential and non-residential sectors of the city, which does not ensure the integrated use of solid waste as technogenic raw materials;
- loss at the stage of sorting of many valuable components (only metals are extracted, the isolation and practical use of other valuable components is difficult due to their severe pollution when sorting the entire mass of solid waste generated);
- reduced efficiency of mechanized sorting, especially screening of solid waste, due to the presence of large fibrous and film components (the holes of the screens are clogged, the output of the sieve product is reduced);
- reduced efficiency of separation (removal) from solid waste of hazardous and some ballast components (for example, spent dry galvanic elements), which reduces the environmental friendliness of both thermal and biothermal processing of enriched solid waste fractions due to contamination of exhaust gases and compost (primarily heavy metals).

 An object of the invention is to increase the efficiency of sorting and processing urban solid waste and minimizing the amount of waste sent to landfill.

 The stated technical problem is solved in such a way that in the method of processing municipal solid waste, including their sorting, thermal and biothermal treatment of sorted products, the waste of the residential and non-residential gas sector of the city is separately sorted to produce valuable components, intermediates and tailings, while the waste of the city's residential sector is subjected to sequential magnetic separation with the release of ferrous metals into the magnetic fraction, separation of the non-magnetic fraction with the release of fibrous and film components, primary screening of separation tails to obtain an under-sieve and over-sieve product, aeration separation of an under-sieve product with separation of light and heavy fractions, magnetic separation of the heavy fraction with the extraction of ferrous metals, electrodynamic separation of a non-magnetic fraction with extraction of non-ferrous metals, secondary screening of the tails of electrodynamic separation and resolution . At the same time, valuable components (recyclables) and dangerous and ballast components are isolated from the over-sizing product of primary screening by manual sorting. In addition, the subgrate secondary screening product is sent for biothermal treatment, and a class of 60 +40 mm is extracted from this product (extraction of hazardous components). At the same time, fibrous and film components, a light fraction of air separation, over-sizing products of primary and secondary screening are sent for heat treatment.

 The invention consists in the following.

 As a result of the studies, it was possible to optimize the integrated processing of urban solid waste based on separate enrichment of waste from the residential and non-residential sectors of the city, which can significantly increase the extraction of valuable components, remove hazardous components, and separate combustible and biodegradable fractions from residential sector waste, respectively, for subsequent thermal and biothermal processing, and from non-residential sector waste - tailings for subsequent heat treatment. At the same time, waste from the residential sector of the city with the aim of extracting valuable components, removing hazardous and ballast components and isolating intermediates (combustible and biodegradable fractions) is subjected to magnetic separation in series with the separation of ferrous metals into the magnetic fraction, separation of the non-magnetic fraction with the release of fibrous and film components, the primary screening the tailings of the separation of fibrous and film components to obtain an under-sieve and over-sieve product, air separation of the sieve product with the release egkoy and heavy fractions, magnetic separation of the heavy fraction with additional extraction of ferrous metals, non-magnetic fraction electrodynamic separation with the recovery of non-ferrous metals, tailings screened secondary electrodynamic separation with isolation of oversize and undersize product. At the same time, valuable components (recyclables) and dangerous and ballast components are isolated from the over-sizing product of primary screening by manual sorting. In addition, the subgrate secondary screening product is sent for biothermal treatment, and a class of 60 +40 mm is extracted from this product (extraction of hazardous components). At the same time, fibrous and film components, a light fraction of air separation, over-sizing products of primary and secondary screening are sent for heat treatment. The invention is illustrated in the drawing, where figure 1 shows a diagram of the technological process of integrated processing of solid waste.

 An example of a specific implementation of the described invention.

 Studies were conducted on samples of solid waste from the residential sector of the city.

 Ferrous metals are extracted from the residential sector of the city, transported by belt conveyors with a stepwise increase in the speed of the transported stream (in order to ensure a monolayer supply of waste to the sorting process), using magnetic separation (the first stage of magnetic separation). The magnetic product is cleaned in a magnetic field in order to obtain a conditioned product. The non-magnetic fraction of the MSW stream is subjected to separation to extract fibrous (textile) and film components that are sent for heat treatment by pruning; tails of this separation are screened according to the class of 250 mm. The class + 250 mm is sent for heat treatment, the class - 250 mm is subjected to air separation with the release of light and heavy fractions. The light fraction is sent for heat treatment, ferrous metals are extracted from the heavy fraction of aeroseparation using magnetic separation (2nd stage of magnetic separation); The magnetic product is cleaned in a magnetic field. Magnetic separation tails are subjected to two-stage electrodynamic separation in order to extract non-ferrous metals. Tails of electrodynamic separation are screened according to the class of 60 ÷ 100 mm in order to isolate a biodegradable fraction in the sublattice product for biothermal treatment; Oversize product is sent for heat treatment.

 The experiments showed that the timely removal of fibrous and film components from the MSW stream prevents clogging of the lifting and transport tract and sorting devices installed in the line, significantly optimizes the operation of screening the MSW (the efficiency of separating solid waste by size increases by 8-10%).

 In the table. 1-4 shows data confirming the validity of the described technical solution.

 In the table. Figures 1 and 2 show the composition of individual fractions of solid waste separated during sorting and the combined product, which is a combustible fraction, sent for heat treatment. As can be seen from the tables, the combustible fraction is formed from textile (fibrous) components, light (waste-forming) components and material with a grain size of + 60 (+ 100 mm). The output of the combustible fraction depends on the size of the allocated biodegradable fraction at the stage of secondary screening. The choice of separation size depends on specific practical conditions: demand for products, productivity of equipment, etc. With increased demand for energy (for example, in winter), it is preferable to increase the output of the combustible fraction and, accordingly, carry out secondary screening in the class of 60 mm (see table . 3). With increased demand for compost, it is preferable to increase the yield of the biodegradable fraction and, accordingly, carry out secondary screening in the class of 100 mm (see table 4). Conducting secondary screening in a class of less than 60 mm leads to a decrease in the calorific value of the combustible fraction (less than 1800 kcal / kg). When screening in a class of more than 100 mm, the yield of the combustible fraction is significantly reduced.

 As can be seen from the table. 1 and 2, the combustible fraction in its composition and calorie content meets the most stringent requirements of any thermal process: does not contain metals and harmful impurities, is characterized by a sufficiently high calorific value (up to 2500 kcal / kg compared to the calorific value of the initial solid waste 1500-1800 kcal / kg) forms little slag.

 As can be seen from the table. 3 and 4, the biodegradable fraction contains at least 65% food and vegetable waste and can easily be biothermally treated.

 Thus, the described method allows, on the basis of separate sorting and processing of waste from the residential and non-residential sector of the city, to identify valuable components, intermediates of optimal composition and tailings with the least cost and without negative environmental impact. The specific capital costs for the implementation of the described method are $ 300 / t, which is two times lower than the prototype ($ 600 / t), in prices at the beginning of 2002.

Claims (5)

 1. A method for the integrated processing of urban solid household waste (MSW), including their sorting, thermal and biothermal treatment of sorted products, characterized in that the waste is separated from the residential and non-residential sector of the city to produce valuable components, intermediate products and tailings, while residential waste sectors of the city are subsequently subjected to magnetic separation with the release of ferrous metals into the magnetic fraction, separation of the non-magnetic fraction with the release of fibrous and film components, primarily screening of separation tails to obtain an under-sieve and oversize product, aeration separation of an under-sieve product with the separation of light and heavy fractions, magnetic separation of the heavy fraction with the extraction of ferrous metals, electrodynamic separation of a non-magnetic fraction with the extraction of non-ferrous metals, secondary screening of the tails of the electrodynamic separation with separation .  2. The method according to p. 1, characterized in that the secondary raw material in the form of valuable components, hazardous and ballast components are isolated from the oversize product of primary screening by manual sorting.  3. The method according to p. 1 or 2, characterized in that the subgrate secondary screening product is sent for biothermal treatment.  4. The method according to any one of paragraphs. 1-3, characterized in that hazardous components with a particle size of -60 + 40 mm are isolated from the subgrate secondary screening product.  5. The method according to any one of paragraphs. 1-4, characterized in that the fibrous and film components, a light fraction of air separation, over-sizing products of primary and secondary screening are sent for heat treatment.

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