RU2100093C1 - Electromechanical separator - Google Patents

Abstract

FIELD: cleaning and separation of loose materials, for example, agricultural products. SUBSTANCE: electromechanical separator includes cylindrical housing with coaxial cylinders of different height mounted on its base, three horizontal conducting platforms located one under another and made in form of disks whose diameters decrease downwards. Platform of maximum diameter is secured on second (from housing) cylinder at level of first cylinder, platform of average diameter is secured on fourth cylinder at level of third one and platform of minimum diameter is secured on sixth cylinder at level of fifth cylinder. First and second platform are provided with holes forming screen. Diameter of holes in first platform exceeds that of holes in second platform. Circular electrode is fitted at edge of each platform. Axle of electric drive passing through centers of platforms is connected with impellers mounted on platforms and with rocker arms carrying the brushes located in circular gaps between cylinders and brought in contact with base provided with holes in each gap. EFFECT: enhanced efficiency. 5 cl, 3 dwg

Description

 The invention relates to a device for the separation of bulk materials and can be used to clean crops from collapsed shell, various impurities using an electrostatic field.

 A known electric seed cleaning machine (ed. St. USSR N503595, cl. 3 B 03 C 7/04, 1974), comprising a hopper-feeder, sieves with sloping boards installed parallel to each other with slope, flat orienting electrodes placed above each sieve, connected to the vibrator, inclined troughs installed at the lower ends of the sieves, a conveying device made in the form of a belt conveyor with holes vertically located directly behind the troughs, a drive shaft for rotating the conveyor shaft, an arc-shaped electrode placed near from the conveyor belt, behind which there is a confuser with a suction fan associated with the cyclone, and receiving hoppers.

 The disadvantage of this machine is the inability to quality separation of the mixture, in which the components of one type in comparison with the components of another type in the average ratio have less weight (dimensions) and electrical conductivity (worse polarizability). With this combination of properties (characteristic, in particular, for a mixture of kernels and a broken cedar, sunflower shell), the difference in the behavior of both components in the electric field is eliminated by the components of the first type (small kernels) reacting to the action of the orienting electrode field due to their low weight (having reduced electrical conductivity ), while the components of the second type (a relatively large shell) exhibit a similar reaction due to increased polarizability. As a result, the efficiency of the sieve decreases.

 The ability to separate heterogeneous components with the indicated combination of properties is lost in the electric field between the arc-shaped electrode and the conveyor belt. Depending on the magnitude of the field strength, they will either stick to the tape and be carried out by it in the waste bunker, or, without reaching the tape, fall under their own weight into the bunker of a full-fledged product.

 In addition, this machine is not productive enough due to the low speed of the mixture on the sieves under the influence of vibration. When you try to increase the speed by increasing the amplitude-frequency parameters of vibration or the angle of inclination of the sieves, their performance deteriorates due to a decrease in the likelihood of components getting into the holes, and there is also a danger of the mixture falling from the sieves and its avalanche convergence.

 Closest to the technical nature of the proposed device is selected as a prototype electric seed cleaning machine (ed. St. USSR N540672, cl. 3. B 03 C 7/04, 1974), containing a hopper feeder, a sieve in the form of a pyramid located underneath upwards, over which a directing electrode is installed of a similar shape, a vibrator connected to the sieve interacting from below with brushes, conveying devices in the form of drums placed at the output ends of the sieve faces, arcuate electrodes, partially covering the bar bans drum rotation drive shafts and arranged below them receiving hoppers.

 The disadvantage of this machine is the low quality of separation of a mixture containing heterogeneous components, the behavior of one type of which during the separation process is dominated by the weight factor over polarizability, and of another type, on the contrary, the ability to electrify determines the response to an electric field. In other words, a component with a small weight and a dielectric constant (electrical conductivity) behaves in an electric field in the same way as a component of another type, which has a large weight and high permeability. With this combination of properties, the resulting forces acting on each component (consisting of the Coulomb and gravitational forces) turn out to be close in magnitude, which eliminates the separation of the mixture in the electric separation zone between the drums and arcuate electrodes, namely, at a low field strength, some components do not reach the drums due to due to insufficient Coulomb gravity, and others due to the prevailing gravity. On the other hand, both types of components stick to the drums at high field strengths: one type due to its low weight, the other due to its better electrification ability. In both cases, their separation by type is not achieved.

 In addition, this separator has low productivity due to the low throughput due to the use of a single sieve, as well as due to the low speed of movement of the mixture through it in a continuous stream under the action of vibration. The throughput of this design is determined by the diameter of the outlet of the hopper-feeder and does not depend on the width of the face of the sieve at the base of the pyramid, since there are no effective forces causing the mixture to move to its ribs in an expanding flow. When the vibration frequency is increased in order to increase productivity, the sieve's efficiency decreases due to rolling the mixture too quickly. At the same time, increasing the steepness of the faces of the pyramid also affects the sieving ability of the sieve. The mixture flows rapidly from the top along the shortest path in the middle of the faces.

 The purpose of the invention to improve the quality of separation and performance.

 The goal is achieved in that in an electromechanical separator containing a hopper-feeder, a sieve located underneath it, brushes interacting with it, a conveying device with a drive shaft, and electrodes, there are additionally coaxial cylinders of different heights installed in the cylindrical body, forming annular rings gaps, three horizontal fixed platforms of conductive material, the diameters of which decrease from top to bottom, and the platform of the largest diameter is fixed to the second from the cylinder housing at the level of the upper edge of the first cylinder and has a specified sieve, the diameter of which does not exceed the diameter of the second platform, mounted on the fourth cylinder from the body below the first platform at the level of the upper edge of the third cylinder and also has a sieve, the diameter of which does not exceed the diameter of the third platform, fixed on the sixth from the body of the cylinder under the second platform at the level of the upper edge of the fifth cylinder, and the size of the sieve-forming holes in the first platform is larger than in the second platform through the centers of the boards Form passes the electric drive shaft, rigidly connected with the impellers located on each of them, consisting of a hub with several blades, equipped with brushes and reaching the edges of the platforms, and the conveying device is made in the form of rockers connected to the shaft, carrying other brushes located on the rods located between cylinders in contact with the base, with at least one hole in each gap, and the electrodes are made in the form of rings and are located at the edge of the platforms.

In addition, each blade is offset by an angle of 60 90 ^o from the vertical radial plane passing through the attachment point of the blade with the hub, and is bent in the peripheral section against the direction of rotation.

 On the lower side of the first and second platforms, disks adjacent to them with openings made with the possibility of adjustable overlapping of openings in the platforms are movably mounted, and the first, third and fifth cylinders from the housing consist of two cylinders movably interconnected with each other with height adjustment, the upper the cylinder is made of dielectric material.

 Along with this, brushes located in the gaps between the cylinders are evenly placed on the rings fixed to the rocker arms.

 This embodiment of the device allows to improve the quality of separation due to the preliminary separation of different types of mixture components of similar weight according to the size parameter due to the use of a sieve system with holes of various sizes, as well as due to the uniform and almost piecewise supply of components to the electrostatic separation zone using a system of blades, which aggregate allows you to increase its effectiveness.

 This is facilitated by the displacement of the blades relative to the radial vertical plane and their arched shape, providing a quick removal of the mixture to the edges of the platforms with a smooth decrease in the radial component of the speed of the mixture at the peripheral sections of the platforms, eliminating the unwanted flight of components into the separation zone.

 However, the inventive design of the separator has improved performance achieved through the use of a system of horizontal sieves located one below the other, dividing the mixture into three streams at a time, which increases throughput, as well as due to the accelerated transportation of the mixture using blades to the large total separation zone the length obtained as a result of the arrangement of individual annular zones in the form of a concentric electrostatic system, ensuring compactness of the con truktsii.

 Comparative analysis with the prototype shows that the claimed electromechanical separator is distinguished by the presence of new design features: a system of coaxially mounted cylinders forming annular spaces between each other, platforms of different diameters with sieves having different openings, electrodes in the form of rings installed near platforms, blades, located on the platforms, as well as a conveying device in the form of a system of brushes suspended on the rocker arms located in the spaces between the cylinder ami.

 Thus, the claimed device meets the criterion of "novelty." The applicant does not know analogues and other technical solutions that describe the signs that "the electrodes are made in the form of rings and are located at the edge of the platforms", "coaxial cylinders of different heights installed in a cylindrical body on the base, forming annular gaps with each other holes. "

 Therefore, the proposed object meets the criterion of "inventive step".

 Figure 1 shows the design of the separator; in Fig. 2, section A A in Fig. one; figure 3 plot of the electric separation zone.

 The separator (Fig. 1) consists of a base 1, coaxially mounted on it cylinders 2-8 of different heights, forming annular spaces between each other, and the outer cylinder 2 acts as a separator housing, on which a hopper-feeder 9 is funnel-shaped with a metering device 10 horizontal, electrically conductive platforms 11-13 in the form of disks of different diameters located under the hopper-feeder 9. The platform 11 of the largest diameter is mounted on the second cylinder 4 from the body 2 at the level of the upper edge of the cylinder 3, the platform 12 on the cylinder 6 under the platform 11 at the level of the upper edge of the cylinder 5, and the smallest diameter platform 13 on the cylinder 8 under the platform 12 at the level of the upper edge of the cylinder 7.

 The platforms 11 and 12 have openings 14 forming a sieve (see FIG. 2), the diameter of the sieve in the platform 11 not exceeding the diameter of the platform 12, the diameter of the sieve of which is not larger than the diameter of the platform 13, while the size of the holes in the platform 12 is less than platform 11.

Through the centers of the platforms 11-13 passes the shaft 15 of the electric drive 16, rigidly connected with the impellers 17-19, each of which consists of a hub 20 and several vanes 21 (see FIG. 2) with brushes evenly located on the surface of the platforms with brushes reaching the edges of the platforms. Each blade is offset by an angle of 60 90 ^o relative to the vertical radial plane passing through the attachment point of the blade with the hub, and bent in the peripheral section against the direction of rotation.

 Near the edges of the platforms 11-13 placed electrodes 22-24 in the form of metal rings mounted on the rocker arms 25-27. Alternatively, electrodes 25-27 can be mounted on cylinders 2,4 and 6.

 Rocker arms 25-27 are held by rods 28 with brushes 29 located in the spaces between cylinders 2-8 and in contact with the base 1, in which there are at least one hole 30 in each gap. To accelerate the output of the separation products through the holes 30, the number of brushes can be increased by placing them on the rings 31 attached to the rods 28, which increase the mechanical stiffness of the suspension. Under the holes 30 in the base 1 are inclined grooves 32.

 On the underside of the platforms 11 and 12, additionally adjacent disks 33 and 34 are mounted with the possibility of displacement in the plane of the platforms and having openings for adjusting the overlap of the openings in the platforms depending on the size of the separated mixture, which extends the operational capabilities of the separator.

 Cylinders 3, 5 and 7, acting as cutoffs, can be made of two conjugated components with the ability to control the optimal height relative to the level of the platforms 11-13, and the upper part is made of dielectric material.

 In working condition, in each gap formed by the edges of the platforms 11-13 and the corresponding electrodes 22-24, an electrostatic field of the required intensity is created by connecting them to a high-voltage source 35 (see figure 3).

 The separator works as follows.

 The bulk mixture to be divided into different types of components, having passed the metering device 10, enters the platform 11 and, as a result of rotation of the impeller 17, is moved by the blades 21 to its edge. In this case, part of the components, the sizes of which are smaller than the size of the sieve openings, fall into them and fall on the platform 12, and large heterogeneous components reach the edge of the platform 11, bearing the electric charge acquired from contact with it.

 Rotating simultaneously with the impeller 17, the impeller 18 likewise moves the components of the mixture that are on the platform 12 to its edge, which are also charged when interacting with it.

 Part of the components, whose sizes are smaller than the holes in the platform 12, fall into them and end up on the lower platform 13, where they are carried out using the impeller 19 to the edge of the platform, acquiring a charge.

где α угол между векторами сил F_k и F_g.Having reached the edges of platform 11-13, heterogeneous components divided into fractions by size (weight), under the influence of the Coulomb force (F _k ), detach from the platforms and rush to oppositely charged electrodes 22-24, experiencing gravity (F _g ). The resulting force (Fig. 3) acting on a particular component and determining the steepness of the flight path is

where α is the angle between the force vectors F _k and F _g .

 Since the shells, for example sunflower, have a more pronounced ability to electrify in comparison with grains, the trajectory of the latter is lower, due to which fragments of the collapsed shell fly over cylinders 3,5,7 and fall into the annular spaces between cylinders 2-3, 4-5, 6-7, while the grains are retained by these cylinders and end up in the spaces between the cylinders 3-4, 5-6 and 7-8.

 Using brushes 29, components, separated both in appearance and size, are assembled from the base 1 and out through openings 30 through the channels 32.

 Mechanical calibration of the mixture with the help of sieves in the platforms makes it possible to isolate fractions of similar heterogeneous components on them (of the same mass with equal specific gravities), which makes it possible to improve the quality of their electrical separation, using the difference in flight path due to only one factor with different electrification capabilities heterogeneous components.

 The use of the system of blades ensures uniform and almost piecewise supply of components to the electric separation zone, and the location and shape of the blades provide smooth feeding, which together also contributes to an increase in separation efficiency.

 Using a system of horizontal platforms with sieves allows you to simultaneously divide the mixture into three streams, which increases the throughput of the separator, and the introduction of the blades increases the speed of transportation of the mixture into the electric separation zone of a large total length, obtained as a result of the arrangement of individual annular zones in the form of a compact concentric electrostatic system, which overall improves separator performance.

Claims (5)

 1. Electromechanical separator containing a hopper-feeder, a sieve located underneath it, brushes interacting with the sieve, a conveying device with a drive shaft, and electrodes, characterized in that it has a cylindrical body, coaxial cylinders of different heights mounted on it, forming annular spaces between themselves, three horizontal, fixed platforms in the form of disks of conductive material, the diameters of which decrease from top to bottom, and the platform of the largest diameter is secured to the second from the cylinder body at the level of the upper edge of the first cylinder and has the specified sieve, the diameter of which does not exceed the diameter of the second platform, mounted on the fourth cylinder from the body under the first platform, at the level of the upper edge of the third cylinder and also has a sieve whose diameter does not exceed the diameter of the third platform fixed on the sixth cylinder from the housing under the second platform at the level of the upper edge of the fifth cylinder, and the size of the sieve-forming holes in the first platform is larger than in the second platform through the centers of the platforms, an electric drive shaft passes rigidly connected to the impellers located on each of them, consisting of a hub with several blades, equipped with brushes and reaching the edges of the platforms, and the transporting device is made in the form of rockers connected to the shaft, carrying other brushes located on the rods located between cylinders in contact with the base, with at least one hole in each gap, and the electrodes are made in the form of rings and are located at the edge of the platforms. 2. The separator according to claim 1, characterized in that each blade is offset by an angle of 60 90 ^o from the vertical radial plane passing through the attachment point of the blade with the hub, and is bent in the peripheral section against the direction of rotation.  3. The separator according to claim 1, characterized in that on the lower side of the first and second platforms, disks adjacent to them with holes made with the possibility of adjustable overlapping of the holes in the platforms are movably mounted.  4. The separator according to claim 1, characterized in that the first, third and fifth cylinders from the housing consist of two cylinders movably conjugated to each other with height adjustment, the upper cylinder being made of dielectric material.  5. The separator according to claim 1, characterized in that the brushes located in the spaces between the cylinders are evenly placed on the rings mounted on the rods of the rocker arm.

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