SU1623794A1 - Sieve for vibratory screen - Google Patents

Abstract

The invention relates to a technique for the separation of materials by size and can be used in the mining and processing and other industries. The purpose of the invention is to increase the efficiency of screening by changing the amplitude-frequency parameters of the vibrations of the screening surface along the length of the sieve. The sieve contains the strings (C) 3 in the form of elastic elements fixed on the side supports 2 and the central support 4. The length of the support} is less than the length of the sieve and it is installed with a gap relative to its loading end. When the sieve is operating, the C 3 resonates under the influence of vibrations. Since the support 4 is installed with a gap, the C 3 oscillates with different amplitudes along the length of the sieve. For fixation of C 3 in the middle between supports 2 and 4, additional supports 5 are placed in zone III of the sieve, at an equal distance from supports 2 and 4. The length of the supports 5 installed from the discharging end of the sieve is less than the support's length 4 h c f-ly , 2 Il.

Description

The invention relates to techniques for the separation of bulk materials by screening, in particular, for the design of sieves with elastic screening surfaces, and can be used to classify difficult-to-screen materials in mining, metallurgical and other industries.

The purpose of the invention is to increase the efficiency of screening by changing the amplitude-frequency parameters of the oscillations of the screening surface along the length of the sieve.

In FIG. 1 is a schematic diagram of a sieve; in FIG. 2 - graphs of the amplitudes of oscillations in the sieve zones.

The sieve consists of a frame 1 (Fig. 1), which is mounted in a known manner on a vibrating screen and having side supports 2, in which the ends of the elastic elements 3 are pre-tensioned. The elastic elements are strings or ribbons with protrusions and, being parallel to each other, frame planes form a screening surface. The sieve is provided with a central support 4, which is located in the midline between the side supports 2 from the discharge end of the sieve towards the loading. The length of the support 4 is less than the length of the sieve, and the support provides a rigid fastening of the middle of the elements 3, excluding zone I.

The design gets further development with the introduction of additional supports 5, which are located between the central 4 and side 2 supports, at an equal distance from them. The length of the additional supports installed from the discharge end of the sieve is less than the length of the central support. Additional supports 5 provide a fixation of each of the elements 3 in the middle between the side and central supports in zone III of the sieve length.

The separation of the sieve along the length into zones I - III is determined by the technological features of the screening material and depends on the lengths of the central and additional supports. Obviously, a new series of additional supports can be introduced from the loading end of the sieve, more fractionally dividing the length of the elements 3.

The sieve can be made either from elements of equal length, or from elements of lengths corresponding to the distance between the supports in different zones of the sieve.

The sieve works as follows.

When the screen operates under the influence of the driving force of the vibrator transmitted to the sieve (coordinated for energy and economic reasons with the frequency of natural oscillations of the screening surface), the elements of the 3 sieves resonate and acquire vibrations. Moreover, the vibrations of the elements 3 in zone I have a resonant frequency, in zones II and III the frequencies of the first and second harmonics, i.e. along the length of the sieve from the input to the output end, the frequency of the excited oscillations of the screening surface increases. The amplitude of oscillations of elements 3, the maximum in zone I, decreases in proportion to the fractional lengths of elements 3 in zones II and III (Fig. 2), i.e. the oscillation amplitude of the screening surface decreases from the input to the output end of the sieve. The material supplied to the inlet end of the sieve is divided into sub-sieve and sieve products under the influence of vibrations of the screening surface. When passing over-sieve material along the length of the sieve in its composition, the content of particles of the under-sieve fraction decreases, which requires a decrease in amplitude and an increase in the frequency of vibration exposure and is ensured by successive passage of zones I, II, III.

Claims (2)

Claim 1. A sieve of a vibrating screen, including a screening surface formed by string elastic elements located across the direction of movement of the material and mounted on the side and central supports, the last of which is located at the same distance from the side supports, characterized in that, in order to increase the efficiency of screening for due to changes in the amplitude-frequency parameters of oscillations of the screening surface along the length of the sieve, the central support is made shorter than the length of the sieve and o sieve end with a gap relative to its loading end. 2. A sieve on and. 1, characterized in that it is equipped with up to 11o. ιni pl ι, with the supports installed on the side of the fold: the weft end of the sieve in the middle between the central and side supports, and the length of which is less than the length of the central support.