RU2484905C2 - Vibrating screen for sizing solid household wastes - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to treatment of solid household wastes and may be used at refuse processing plants etc. Proposed screen comprises box, vibroexciters and working surface composed of several horizontal tiers. Every ties is made up of transverse bearing beam and parallel wedge-like fire plates attached thereto by their one end, their opposite end being free. Fire-bar plate of every tier form screening clearance between them. Physical parameters of plates are selected to ensure plate free oscillation frequency complying with the condition 1.05 f_for<f_f<1.20 f_for, where f_f is frequency of said free oscillations, f_for is frequency of forced oscillations of the plates.

EFFECT: higher efficiency of screening and effect of screening surface self-cleaning.

2 dwg, 1 tbl

Description

The invention relates to the field of processing of municipal solid waste (MSW) and can be used in waste processing plants and at enterprises for the transshipment of municipal solid waste (transshipment stations), conducting preliminary sorting of waste.

Currently, an urgent task is the machine sorting of non-selectively collected solid waste with their separation into a potentially business fraction suitable for subsequent recycling, and into an organic fraction sent for composting or disposal at landfills. In the original MSW, the business fraction is represented by dry plastic, metal, cardboard packaging and the like, and the organic fraction is represented by food waste, wet paper, wet film materials.

The morphological composition of the non-selectively collected solid waste is such that the contents of the potentially business fraction and organic fraction are usually close in mass.

The common properties of the components representing the business fraction are their dry state, high coefficient of elasticity, low coefficient of friction.

The common properties of the components of the organic fraction are increased humidity, ductility, high coefficient of friction.

The most common method of primary mechanized sorting of solid waste is to separate them into business and organic fractions by classification on low-speed drum-type screens with round or polygonal drums with a typical mesh size of 70-100 mm.

The efficiency of such sorting is low, while drum screens are often clogged with film materials - polyethylene, nylon, which leads to the need for frequent equipment shutdowns and, consequently, a low utilization rate of equipment (Zhurkovich V.V. Waste. Scientific and educational manual. St. Petersburg. : Humanism, 2001).

The use of manual dismantling of solid waste as an operation of the primary sorting of waste cannot be considered as an acceptable method due to the low productivity of manual labor, the inevitably poor sanitary conditions, etc. Manual disassembly can be effective, with certain reservations, only with the secondary sorting of a business fraction already separated from the garbage.

A known application for sorting solid waste is vibrating screens with flat screens having rectangular or circular cells, widely used, for example, in the mining industry (Rodionov A.I. et al. Environmental protection engineering. - M .: Chemistry, 1989). The screen of the indicated type is a box open from the discharge end, equipped with flat screens. Circular or narrowly directed vibrational vibrations are attached to the screen box (Reference for ore dressing. Preparatory processes / Edited by O.S. Bogdanov. - M.: Nedra, 1982). Vibrating screens are much more compact and lighter than drum screens. However, attempts to use such screens did not yield positive results. This is due to the fact that, in contrast to heavy mineral raw materials, municipal solid waste has a low bulk density (0.2-0.4 tons / cubic meter) and cannot be processed on flat cellular screening surfaces with sufficient productivity. Vibrating screens with cellular screening surfaces are also prone to clogging the surface with film and wet components. In addition, the physics of vibration classification on cellular screening surfaces does not provide an effective sorting of solid waste into elastic business components and inelastic organic ones.

A technical solution is known aimed at reducing the clogging of the surface of a vibrating screen designed to classify solid materials, which consists in equipping the screen with rows of cantilevered finger-shaped rods (US patent US 05398815 A, priority dated March 31, 1994). The use of screens with cantilever grates in the form of rods can improve the classification efficiency of clay materials and crushed stone with a high content of small particles. It is indicated that such screens have significant limitations on the size of the feedstock (L. Vaysberg. Screening surfaces of screens. Designs, materials, application experience. / L.A. Vaysberg, A.N. Kartavyi, A.N. Korovnikov. - St. Petersburg .: VSEGEI, 2005, pp. 119-120). Screens of this type have found limited application in the industry of non-metallic building materials and have not found practical application in the technologies for sorting municipal solid waste.

The latter is obviously connected with the fact that the grate rods should have a sufficiently large cross section for mechanical reliability, and this, in turn, leads to a small amplitude of the grate oscillations and the absence of the self-cleaning effect of the grate from adhering wet and film materials present in the MSW.

A technical solution is known, adopted as a prototype, aimed at reducing the clogging of the surface of a vibrating screen designed to classify waste, consisting in equipping the screen with stepwise arranged rows of cantilevered trapezoidal (wedge-shaped) vertical projections of grid-irons installed with gaps (Ustinov I.D. New equipment for the classification of waste and screenings. - Industrial Herald, 2010, No. 9, p. 40). The screen was developed at NPK Mekhanobr-tekhnika. During the passage of the initial household waste along the separating screen of the screen, the elastic components of solid waste bounce off the surface of the grates and go into the upper screening product, and the moist, plastic components pass through the gaps between the grates and enter the lower screening product. Thus, the separation of the initial solid waste into business and organic fractions is ensured. Due to its high productivity and good separation characteristics, the screen has found industrial application in waste processing plants.

The disadvantage of the prototype is that the screening surface has a low ability to cleanse itself, although more than that of vibrating screens with grates in the form of rods or drum screens. The reason for this is that the wedge-shaped grate-irons used in the design of the prototype screen for reasons of mechanical strength have a small length and considerable thickness with a small amplitude of forced vibrations, insufficient for self-cleaning of the grate-irons. At the same time, at the stage of the prototype creation, the use of grates of a different configuration using high-quality structural materials for their manufacture was not considered.

The present invention is directed to solving the urgent task of increasing the efficiency of the vibrating screen for the classification of solid waste by enhancing the effect of self-cleaning of the separating surface.

It is known that the frequency of free vibrations of cantilever fixed elements (beams) depends on the basic physical parameters of the beam as follows (Ponomarev SD and others. Strength calculations in mechanical engineering. T.3 - M .: Mashgiz, 1959, p. 266- 297):

f _c = 3.52 (Ej / q) ^-2 / L ² ,

where f _c is the frequency of free vibrations,

Ej is the stiffness of the beam section,

q is the mass of a unit length of the beam,

L is the length of the beam.

Taking into account this dependence, we propose the design of a screen for sorting solid waste, which includes well-known structural elements - a box, a vibration exciter and a work surface made in the form of several horizontal tiers. Each tier is formed by a transverse support beam and parallel wedge-shaped grate plates attached to it at one end in a vertical projection. The opposite end of the plates is left free. The grid-irons of each tier form sifting gaps among themselves. The main feature of the proposed technical solution is that in order to effectively self-cleaning plates plates physical parameters are selected in such a way that their free oscillation frequency was slightly higher frequency of forced vibrations, and was particularly in the range of up _to 1,05 f 1,20 f _at

Key parameters of the invention are associated with the achieved technical effect as follows:

- the physical and mechanical properties of the grate plates are selected so that the free vibration frequency is higher than the forced vibration frequency initiated by the screen exciter by 1.05-1.20 times;

- thus, the screen operates in the near pre-resonance region of the grate oscillations, which ensures the self-cleaning effect of the grate when they are contaminated during operation and, accordingly, provides high technological parameters for sorting solid waste;

- closer than 1.05 times the deviation of the free oscillation frequency of the plates from their forced frequency translates the functioning mode of the working surface of the screen into a zone of practical resonance, dangerous for the mechanical reliability of the machine;

- at a frequency of free vibrations that differ in a larger direction by more than 1.20 times from their free frequency, grate plates will be inactive in a vertical plane and will not provide a self-cleaning effect;

- the design of the screen for sorting solid waste with a free oscillation frequency higher than 1.20 times their forced frequency, corresponds to the sedentary mode of operation of the grate plates of the prototype and all analogues of grate screens and meets the conditions of experiment No. 1 in the table of test results below.

The proposed design of the screen for sorting municipal solid waste is shown in figure 1 and figure 2. The design is a box (5) with side flanges (1, 2) and a flange on the loading side (3) and open on the unloading side. The flange on the loading side may be in the form of a tray. The box is equipped with a vibrator (4), which informs the box of vertical orbital or rectilinear vibrations. The box is installed at an angle of 0-25 ° to the horizon. The box is equipped with transverse support beams with parallel-wedge-shaped grate plates (6) attached to them at one end in vertical projection, which together with the support beams make up rows of horizontal tiers. Tiers make up the working surface of the screen. The grid-irons of each tier form sifting gaps among themselves. The loose ends of the grate are directed towards the discharge of the screen. The rigidity, length and thickness (respectively mass) of the grid-irons are selected so as to ensure the frequency of free (resonant) oscillations of the plates in the range from 105 to 120% of the frequency of forced oscillations of the plates at idle speed of the screen.

Such a new technical solution provides for self-cleaning of the surface upon adhering to the grate surface of wet plastic materials and films due to the transition of grate bars to the near pre-resonance region of vibrations, accompanied by an increase in the amplitude of their vibrations. The effect of the transition of the vibrating cantilever elements to the region close to the resonance when the mechanical load increases on them is consistent with the principles of theoretical vibration mechanics (Blekhman II, Vibration mechanics. M .: Fizmatlit, 1994), but was not previously used in the construction of vibrating screens with sieving surfaces console type.

The vibration exciter is made adjustable, with the possibility of achieving the above frequency parameters of the forced vibrations.

The form of vibrational vibrations of the screen box itself — orbital or rectilinear, according to the same principles of vibration mechanics, does not matter, since it does not affect the frequency characteristics of cantilever grates.

Vibrating screen works as follows.

When loading initial solid household waste onto the screen, they move under the influence of vibration and gravity from the loading zone to the side of the screen unloading zone, moving sequentially from one tier to another, on each of which the waste is impacted by vibrating grates, causing the material to loosen. As a result, the elastic components are separated from the wet plastic ones, bounce off the vibrating surfaces of the grates, reach the outlet and go into the upper screening product.

And wet, plastic components pass through the gaps between the grates and fall into the armrest space, leaving the lower screening product. Thus, the separation of the initial solid waste into business and organic fractions is ensured.

When the grate bars of the separated material adhere to the surface of the plates, their mass increases, the frequency of their forced oscillations approaches the resonant frequency (the first free vibration frequency), which is accompanied by an increase in the amplitude of the oscillations of the cantilever grates and the surface is self-cleaning. After self-cleaning, the system returns to its original state.

Thus, the main distinguishing feature of the claimed technical solution is that the rigidity, length and mass of the grate plates should be such that the frequency of free (resonant) vibrations of the plates is close to the frequency of their forced vibrations, but higher than the frequency of forced vibrations.

An example of the implementation of the proposed technical solution in practice.

A semi-industrial screen designed for sorting solid waste was tested. The working surface of the screen is made in several horizontal tiers. Each tier is formed by a transverse support beam and cantilever plates attached to it, wedge-shaped in vertical projection with bases of 60 and 30 mm, 200 mm long and 3 mm plate thickness, made of G65 spring steel with a natural free vibration frequency of 28 Hz and the amplitude of oscillations of the end of the platinum idling 3 mm with a box frequency of 16 Hz. The measured forced oscillation frequency of the end of the grate at idle of the screen was 24 Hz. Thus, the free oscillation frequency of the grate was 116% of the forced frequency. The dividing surface of the screen consisted of five rows of cantilever grate-irons, six grate-irons in a row and a nominal inter-grate slit of 35 mm.

When loading test bodies — a mixture of wet pieces of a plastic film 120 μm thick with a size of 200 × 200 mm and aluminum used cans with a diameter of 70 mm and a height of 120 mm — typical for MSW, a partial short-term sticking of pieces of polyethylene to the surface of the grate was observed, which was accompanied by increasing the measured forced oscillation frequency to 26 Hz with an amplitude of 5 mm and a clear effect of complete self-cleaning of the surface of the grate.

The samples of polyethylene that came down from the surface of the grid-irons passed into the lower screening product, and the samples of the business fraction - aluminum cans completely passed into the upper screening product.

In addition, we conducted an additional experiment to increase the grate mass by 20% by placing glued weights on the ends of the plates at the bottom of the grate, which led to an increase in the forced oscillation frequency when test bodies adhered to 27 Hz and the amplitude of the grate ends oscillation to 7 mm with full self-cleaning effect of grid-irons.

Comparative tests were carried out on a screen of a previously known design, that is, a screen with 6 mm thick plates made of St3 tool steel, own free vibrations of 32 Hz and forced vibrations at idle 24 Hz with an amplitude of 1.5 mm. When loading test bodies from a wet plastic film, persistent sticking of the surface of the grate was observed in 25% of cases without a noticeable self-cleaning effect.

The experimental results justifying the limits of the agreed frequency parameters of the grate plates are shown in the table.

Table No. of experiments one 2 3 four 5 Free frequency, Hz 26.9 27.6 28.0 29.5 31.3 Forced frequency, Hz 21.5 23.0 26.0 28.1 30.1 Freedom ratio frequency to forced,% 125 120 110 105 104 Sticking,% of the number of observations fifteen one 0 0 0 Note Inefficient area Field of high technological results Technically risky resonance region

From the above table it follows that in the field of the claimed screen parameters — when the ratio of the frequencies of free and forced vibrations of the grate plates is 105-120% — the effect of self-cleaning the surface of the grate is observed (experiments 2-4). In other words, the physical parameters of the plates (namely, the length, width, thickness, stiffness of the material) must be selected so that the condition is met:

1.05f _in ≤f _with ≤1.20f _in ,

where f _{with the} frequency of free (resonant) oscillations of the plates,

f _in - frequency of forced oscillations of the plates

With a larger frequency ratio, self-cleaning indicators are sharply deteriorating. When the frequency ratio is close to the resonance (experiment 5), the self-cleaning effect is present, however, this area should not be considered technically justified due to the high risks of mechanical destruction of the grate during prolonged operation in this mode.

Claims (1)

A vibrating screen for sorting solid household waste, including a box, a vibration exciter and a work surface made in the form of several horizontal tiers, each tier being formed by a transverse support beam and parallel wedge-shaped gantry plates attached to it by one end, the vertical end of which is left free, while the grid-irons of each tier form sieving gaps between themselves, characterized in that the physical parameters of the plates are selected in such a way at once to ensure the frequency of free vibrations of the plates corresponding to the condition
1.05f _in ≤f _with ≤l, 20f _in ,
where f _with - the frequency of free vibrations of the plates;
f _in - the frequency of forced oscillations of the plates.

Images