RU2106206C1 - Multistage sizing screen for sizing of sintered ore - Google Patents

Abstract

FIELD: sizing of materials, applicable in mining and metallurgical branches of industry, in particular, sizing of difficulty screened sintered ores of crushing-sizing plants in mines. SUBSTANCE: multistage screen uses a box with sieves, vibrator, shock-absorbers and supports. The axis of symmetry of vibrator unbalanced masses is shifted from the box inertia axis towards the upper sieve at a distance determined by formulae: h = KV(H•m•r)/M,, where K - coefficient equal to 1.8 to 2.5; H - box height, m; m x r - kinetostatic momentum of vibrator, kgf.m; M - box mass, kg. EFFECT: enhanced efficiency. 2 dwg

Description

 The invention relates to a device for the separation of materials by size and can be used in the mining and metallurgical industries, in particular for the dawn of refractory ores of crushing and screening factories in mines.

 The Mogensen multi-deck screen is known, containing a box with five inclined sieves, a vibration exciter and shock absorbers (Guide to ore dressing. Prepared processes. Edited by O.S. Bogdanov, V. A. Olevsky, 2nd ed., Revised. and additional M: Nedra, 1982, pp. 49-51).

 A disadvantage of the known screen is the low productivity and screening efficiency due to the fact that the pathogen is located on the central axis of inertia of the box, and the same vibration parameters (amplitude, frequency and direction of the trajectories) take place on each sieve along their length, i.e. , the transport and absorption capacity of all sieves are the same, while each of the sieves located along the height of the box performs its own function and requires different vibration parameters. So, for example, the upper sieve is responsible for the intensity of material transportation, i.e., it mainly determines the performance of the screen, and the oscillation parameters of the lower sieve should ensure its high absorbing capacity of the under-sieve fractions, i.e. ensure the quality of the finished product.

A known screen containing a box with a sieve, supports in the form of shock absorbers and struts, an exciter of oscillations located on the central axis of inertia of the duct in the center of the impact, while the axis of the struts are perpendicular to the central axis of inertia of the duct and located at a distance determined by the formula
l = (K • J ₀ ) / m • r, (1)
Where
J ₀ - moment of inertia of the box relative to the racks, kg • m ² ;
m is the mass of the box, kg;
r is the distance from the rack to the center of gravity of the box, m;
K is the coefficient
the vibration exciter is made in the form of an inertial vibrator, and the part of the sieve located behind the uprights is installed at an angle to the horizontal / a.s. USSR N 1119740, class B 07 B 1/40, 1984 /.

 With the centrifugal arrangement of the pathogen on the central axis of inertia of the multi-stage screen box, the segregation ability of all screens in the screen loading and absorption capacity in unloading are intensified with the same transport capacity of all screens, which somewhat increases the efficiency and productivity of the screen, but not enough for sifting difficult-to-screen ores of underground mining.

 In connection with the present invention, the task is to increase the performance of the screen by increasing the transport capacity of the sieve of the upper tier and increasing the efficiency of screening by increasing the absorption capacity of the sieve of the lower tier.

где
K = 1,8 - 2,5 - коэффициент;
H - высота короба, м;
m•r - кинетостатический момент возбудителя колебаний, кг•м;
M - масса короба, кг.The problem is solved in that a multi-tiered screen for sifting sintering ore containing a box with sieves, an exciter of vibration, shock absorbers and supports, has significant features, consisting in the fact that the axis of symmetry of the unbalance of the exciter of oscillations is offset from the central axis of inertia of the box towards the upper sieve by a distance, determined by the formula

Where
K = 1.8 - 2.5 - coefficient;
H is the height of the box, m;
m • r is the kinetostatic moment of the pathogen, kg • m;
M is the mass of the box, kg.

 The combination of essential features allows to obtain a technical result, consisting in increasing the transport capacity of the sieve of the upper tier and the absorption capacity of the sieve of the lower tier, which increases the productivity of the multi-tier screen and its efficiency, i.e. sinter ore quality.

 The shift of the center of gravity of the pathogen from the center of mass of the box to the center of impact on the central axis of inertia and then for multi-sieves perpendicular from the center of impact by value h intensifies the transport capacity of the sieve of the upper tier and the absorption capacity of the sieve of the lower tier.

The physical essence of the result is that the vibration exciter also gave the trajectory of the points of the upper sieve to the sieve plane at an angle β _vs = 15-25 ^o , which provided a high speed of the layer vibration / screen productivity / and the path of the points of the lower sieve to its plane at angles β _ns = 65-90 ^o , which ensured the high absorption capacity of the lower sieve / efficiency and quality of sinter ore /.

 The form of the formula for determining the displacement value - h was obtained using dimensional theory, and the coefficient value - K in this formula was obtained from processing the experimental results shown in FIG. 1, by processing this data on a PC J VM-486, the program "Aprocs".

In FIG. Figure 1 shows graphs of the dependence of screening efficiency - E and screen productivity - Q on the ratio of the square of mixing the exciter to the height of the box - h ² / H for various values of the ratio of the kinetostatic moment of the pathogen to the weight of the box - (m • r) / M; in FIG. 2 shows a proposed multi-tiered screen.

 In FIG. 1, position I denotes the region of rational values of efficiency, II - the region of rational values of productivity, III - the region of coincidence of rational values of efficiency and productivity.

A multi-tiered screen, for example a three-tiered one, consists of a box 1 with sieves - upper 2, middle 3 and lower 4, installed at different angles to the horizon, for example 20, 30 and 45 ^o , and having different hole sizes, for example 0.06 m, 0.025 m and 0.014 m. The box 1 is supported on supports 5 through shock absorbers 6. The vibration exciter 7, for example a two-shaft inertial vibrator, is installed in the loading area of the screen so that the axis of symmetry OO of the unbalance 8 of the vibration exciter is offset from the central axis of inertia of the box O'-O ' 1 towards the upper sieve 2 at a distance - h, defined calculated by the formula / 2 /.

 A multi-tiered screen works as follows.

When the unbalances 8 of the vibration exciter 7 are rotated, inhomogeneous vibrations of the duct 1 are generated both in height and in length, which provides an angle of vibration β _vs = 15-25 ^° on the upper sieve 2, β _ss = 40-50 ^° on the average sieve and lower sieve β _ns = 65-90 ^o . Such angles of vibration of the sieve points are provided by the displacement of the pathogen of vibration of the points of the sieves are provided by the displacement of the pathogen of vibrations 7 upward from the center of shock / TsU / perpendicular to the central axis O'-O 'of inertia of the box 1 at a distance - h. After supplying the initial ore to the upper sieve 2, part of the material, the particle sizes of which are significantly smaller than the openings of the upper sieve, is absorbed by it, falling almost vertically onto the middle sieve 3. Another part of the material, the particle sizes of which are slightly smaller, are equal to or larger than the openings of the upper sieve 2 on it and are discharged either to the underlying sieve 3, or to estrus over-sieve product. The absorption capacity of each underlying sieve 3 and 4 is determined by the ratio of particle and hole sizes, as well as three angular parameters: the angle of inclination of the sieve to the horizontal, the angle between the oscillation path and the plane of the sieve, and the angle of encounter of each particle with the sieve when it falls from the upper sieve to the underlying one. Moreover, the small angles of inclination of the trajectories to the plane of the upper sieve 2 provide a high speed of transportation of material along it, the average angles of inclination of the paths to the plane of the middle sieve 3 provide both rational transportation of the material and its optimal absorption, and large angles of vibration and inclination of the lower sieve 4 provide its high absorption capacity and sufficient transport capacity.

Claims (1)

A multi-tiered screen for sifting sintering ore containing a box with sieves, an exciter of oscillations, shock absorbers and supports, characterized in that the axis of symmetry of the unbalance of the exciter of oscillations is shifted from the central axis of inertia of the box towards the upper sieve by a distance determined by the formula

where K = 1.8 - 2.5 - coefficient;
H is the height of the box, m;
m • r is the kinetostatic moment of the pathogen, kg • m;
M is the mass of the box, kg.

Images