SU859876A1 - Testing sieve - Google Patents

Description

(54) NETWORK ANALYZER

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The invention relates to devices for dividing bulk materials into several classes according to particle size within the granulometric composition of the starting product and can be used both in agriculture and in various industrial fields, such as chemical, building and metallurgical.

The most widely used screen analyzers of the Rotap type and most of the vibratory sieve analyzers are periodic laboratory equipment and cannot be used for automatic control of technical (Yo process). For this purpose, multi-point vibrating screens can be used, but their bulkiness and complexity of the design limit the possibility applications in this direction. Correspondingly, vibration granulometers are used to control the process, however All their known constructions cannot be successfully used as universal ones, i.e. they do not have a sufficiently multivariate mode setting, which is required not only for

increase in sieving efficiency depending on the physical properties of the material, but also to change other

(1 technological parameters, for example productivity.

A sieve analyzer is known, which includes a set of sieves mounted on a housing equipped with unbalanced vibrators and installed through elastic elements on a fixed base on which an electric drive from

This sieve analyzer does not have the option of multivariate adjustment of modes and requires the provision of conditions for self-synchronization of two of its vibrators with scribing axes.

20 The closest to the proposed technical solution is a sieve analyzer, which includes a set of sieves, fastenings on the body, in which the leading 25 shaft is installed under the pinnacles with an unbalanced carrier 2.

Its disadvantage is the low efficiency of screening, screening and the difficult self30 cleaning of screens.

The purpose of the invention is to improve the accuracy and speed of sieving.

This goal is achieved by the fact that the sieve analyzer containing a set of sieves fixed to the housing, in the bearings of which a drive shaft with a carrier mounted is mounted, is equipped with a conical gear pair for rotating the carrier around the shaft axis and the carrier axis. the shaft is perpendicular to its axis and is equipped with movable weights asymmetrically fixed with respect to the axis of the carrier and the axis of the shaft.

The proposed design allows for effective self-cleaning of sieves, therefore, reducing the time required for sieve analyzes. By changing gears and changing the static moment of unbalance, multivariate adjustment of the amplitude and oscillation paths of the analyzer is provided.

The drawing shows a sieve analyzer, a general view.

The sieve analyzer includes a housing 1 with a set of sieves 2 mounted on it and a shaft 3 mounted in bearings 4. The housing 1 is mounted through elastic elements 5 on a fixed base 6 on which is mounted an electric motor 7 connected to the shaft 3 by a lobe coupling 8. In a perpendicular shaft 3 bore, in bearings 9, mounted carrier 10. carrier 10 is equipped with gear 11 and three unbalanced loads 12, and 13 two loads 12 are located symmetrically relative to the axis of the shaft 3 and perpendicular to the axis of the carrier 10, and the third load 13 is located Sno led 10 at one of its ends. The gear wheel 14 is rigidly fixed on the dorpus 1 coaxially with the shaft 3. Each sieve has a discharge chute 15.

The torque from the electric motor 7 is transmitted through a lobe collar 8 to the shaft 3 fixed in the bearings 4. Through the shaft 3, the rotation is transmitted by the carrier 10 and the load 13 located coaxially at one of the ends of the carrier 10, causing the analyzer to vibrate in the horizontal plane. Simultaneously during rotation of the carrier 10 with weights 12, the gear 11 runs around the gear wheel 14, which causes the carrier 10 to rotate around its own axis, causing the sieve analyzer to vibrate in a vertical plane from the centrifugal forces of the loads 12.

Changes in the static moments of loads 12 and 13 lead to the creation of

different in magnitude centrifugal forces. This achieves the multivariate adjustment of the amplitude and oscillation trajectories of the analyzer, which contributes to increased sifting efficiency and self-cleaning of sieves. Changing gears additionally contributes to the creation of a multivariate spectrum of vibration frequencies and ratios of the number of oscillations in the vertical and horizontal planes. For example, the vertical frequency with respect to the horizontal may vary from 4: 1 to 1: 4 or more. Since the carrier 10 is unbalanced relative to its axis and the axis of the shaft 3, the body 1 with the set of sieves 2 can perform very diverse oscillations: from oscillations in the vertical plane to purely hyrational oscillations. The material loaded (the upper sieve is divided into classes according to the number of installed sieves in the kit and each is discharged through a corresponding flow of 15. By determining the volume or weight of each class, you can regulate the process, such as crushing or grinding.

Installing the proposed analyzer in the shop for sieving corundum powders with a capacity of 40 thousand tons per year will reduce the number of sowing devices by 15% and, accordingly, free up part of the production premises. This will make an economic effect of 12 thousand rubles. in year.

Claims (2)

1. USSR author's certificate No. 332368, class C 01 N 15/02, 1968; 2. USSR author's certificate W 542941, class C 01 N 15/02, 1974 (prototype).