UA60254C2 - Method and device for separation of loose mixture in fluid medium - Google Patents

Abstract

Invention relates to the methods and devices for separation of loose materials and can be used in food, chemical and other branches of industry, and in the agriculture. The method of separation of loose mixture in the fluid consists in the gravity feed of particles, aerodynamic monotonically increasing action on them at sharp angle to the vertical line by the cascade of slot jets, which are located in the mode of resonance self-oscillatory motion on the frequency of fundamental harmonic of fluctuations, and discharge of finished fractions. Device for separation contains the bunker with vibrating chute, generator of jets, with flat nozzles located one under another and at sharp angle with the vertical line, the height of cross sections of which, step and angle of installation increase top-down, and the collectors of fractions. Generator is connected with the source of air supply under pressure. In this case, each pair of contiguous nozzles is equipped with resonance chamber connected with their inter-nozzle space. Besides, the chambers have a unit for adjustment of their volume, and the ratio of the height of the cross sections of nozzles to the step of their installation is in the range of 0.2-0.25, and the ratio of the extreme upper and extreme lower angles of installation of nozzles makes 0.65-0.75.

Description

Description of the invention

The invention belongs to methods and devices for air or liquid separation of bulk materials and 2 can be used in food, chemical and other industries, as well as in agriculture to prepare seeds for sowing and for breeding purposes.

There is a known method of separating a loose mixture in a fluid medium, which consists in feeding the particles at the same speed, acting on them with a uniform flow of air and removing the finished fractions (see AS USSR Mo 1176976, MKY VO784/02, publ. 09.07.85, Byul Mo33 "Pneumoseparator of bulk materials"). 70 A known device for separating bulk materials, which contains a fan with an outlet nozzle, a loading hopper located above them and adjacent collectors of finished fractions with a device for screening light particles | see A.S. USSR Mo1763051, MKY В8О0784/02, publ. 23.09.92, Bull. Mo35 "Pneumoseparator of bulk materials".

In known methods and devices, air flow is applied to a single portion of the loose mixture 72 once and only from one random side, so the quality (accuracy) of the separation process is very low, approx. For this reason, similar methods and devices are used, mainly for preliminary cleaning of the loose mixture from light impurities.

The solution closest in technical essence, taken as a prototype, is the method of separating a loose mixture in a fluid medium, which consists in the gravitational feeding of particles, the agrodynamic monotonically increasing action on them at an acute angle to the vertical by a cascade of flat jets and the output of finished fractions. At the same time, the actions are performed in the mode of free variable-sign force scanning with increasing amplitude and scanning angle | see Stalemate. of Ukraine Mo45881 А, MKY 6 В80784/02, publ. 04/15/2002, Byul. Mo4 2002, "Method of separating a loose mixture in a fluid medium and a device for its implementation").

The device for carrying out the method contains a hopper with a vibrating roller, a jet generator installed under it, with flat nozzles located one below the other and at an acute angle to the vertical, the height of the cross sections. (3 of which, the step and installation angle increase from top to bottom. At the same time, the generator is connected to the source of air supply under pressure and is covered by the side walls. The device has fraction collectors located under the nozzles.

Separation of particles according to this method occurs due to the difference in the ratio of their weight and the force of aerodynamic resistance. This method, due to the special mode of action of the jets, is more accurate and more stable over time, especially when separating irregularly shaped particles. This became possible because the action of the flow of the cascade of jets in the scanning mode allows you to approach each particle of the loose mixture multiple times and in different directions. high school

However, the known method and device have the following disadvantages. The variable and free mode of operation (c3 of the cascade of jets inevitably leads to the periodic, unstable in time and space emergence of 39 pressure zones in it and rarefaction with the appearance of direct and reverse currents. In the zone of reverse currents, particles (especially light ones) are drawn into the reverse movement movement of the main flow, which leads to partial mixing of the already separated material. The instability in time of this phenomenon ultimately leads to the opening (rupture) of the cascade of jets at any random place, which further strengthens the reverse flow in this zone and as " the result intensifies mixing. C 50 In addition to all opening, it contributes to the disruption of generation (stopping the oscillatory process), which significantly reduces the quality of separation, bringing it closer to the quality of separation usually with a fan. C" The invention is based on the task of creating a method of separating a loose mixture in a fluid medium and a device for it implementation by optimizing the aerodynamic action in parts by chat material, excluding partial mixing of the final material, which ensures an increase in the quality of separation during multi-fraction separation of irregularly shaped particles. b The problem is solved by the fact that in the method of separating a loose mixture in a fluid medium, that av | consists in the gravitational feeding of particles, the aerodynamic monotonically increasing action on them at an acute angle to the vertical by a cascade of flat jets and the output of finished fractions, according to the invention, the aerodynamic action is carried out in the mode of resonant self-oscillating motion of each jet and the entire cascade of jets at the frequency of the first harmonic at sl 20 fluctuations

The solution to the given problem is also achieved by the fact that in the known device for implementing the method

T" separation of a loose mixture in a fluid medium, which contains a hopper with a vibrating tray, a jet generator installed under them, with flat nozzles located one under the other and at an acute angle to the vertical, the height of the cross-sections of which, the step and the angle, of the installation increase from top to bottom, which connected to the 52 source of air supply under pressure and covered by the side walls, and the collectors of fractions, according to the invention,

GF) each pair of adjacent nozzles is equipped with a resonance chamber connected to them in the space between the nozzles.

In addition, resonant chambers are equipped with a device for adjusting their volume, and the ratio of the caliber of the nozzles to the step of their installation is within 0.2-0.25, while the ratio of the extreme upper and extreme lower angles of the installation of the nozzles is 0.65-0. 75. 60 A distinctive feature of the proposed method of separating a loose mixture in a fluid medium and the device for its implementation is the possibility of obtaining a better separation of particles of a complex shape by excluding back jets and grain flows directly from the separation process.

The technical result of the invention is the possibility of expanding the field of use of the method and device for separating bulk mixtures in a fluid medium by ensuring better separation of the material during multi-fraction stratification by mass, density or specific gravity. At the same time, the possibility of high-quality separation of particles of loose mixture of irregular shape with a minimum amount of impurities is preserved, which is especially important in the selection of agricultural crops.

Use to directly implement the process of separating a cascade of flat jets, which

They are in the self-oscillating mode of interaction with each other at the frequency of the first harmonic, eliminating the "difference" of oscillations in phase, which guarantees the dynamic uniformity of the air flow over its entire live section.

Equipping each pair of adjacent nozzles of a nozzle row with a resonance chamber in the device for implementing the method and connecting it to the inter-nozzle space, regardless of the different calibers of the nozzles, makes it possible to implement the self-oscillating mode of the entire jet system at one resonant frequency, in this case at /o the frequency of the first harmonic fluctuations

The choice of harmonics is explained by the fact that in this mode the process of oscillations of the system is the most stable and has the maximum amplitude, which positively affects the quality of separation.

Introduction to the design of the device for adjusting the volume of resonance chambers allows more accurate resonance. The ratio of the caliber of the nozzles with the step of their installation and the angles of the extreme nozzles in the range of 0.2-0.25 and 7/5 9.65-0.75 excludes the occurrence of self-oscillations at the frequencies of higher harmonics (second, third, etc.).

The entire set of essential features of the proposed solution ensures the achievement of the set goal, the improvement of the quality of multi-fraction separation of the bulk mixture, for example, grain crops, both simple and complex forms of grains, which is very important in agriculture when preparing seeds for sowing and for breeding purposes.

Fig. 1 shows a diagram of a device for implementing the claimed method.

Fig. 2 is a section along A-A of Fig. 1 (section of the nozzle).

The device for implementing the method of separating a loose mixture in a fluid medium consists of a hopper 1 with a vibrating tray 2 for gravity feeding particles into the separation zone. Under the vibrating tray 2, a jet generator 3 is installed, which is essentially a closed volume with a set of a number of flat nozzles 4. The number of the last jets depends on the desired performance of the device, but it cannot be less than three. Height of cross-section of nozzles PN, angle o; their installation to the vertical and the step 7 between the nozzles increases from top to bottom. At the same time, as i) was already mentioned above, n/2-0.2-0.25, and ol/e9.65-0.75.

For example, if the height of the cross section of the upper nozzle is equal to bmm, then the step between the first and second nozzles should be within 20-25mm, etc. When the angle of the upper nozzle is 502, the angle of the lower nozzle should significantly exceed 802 y

Each pair of adjacent nozzles of the row is equipped with a common resonance chamber 5, which has a connection with them between the nozzle space. The cameras have a device for adjusting their volume, made, in this case, in the form of a hinged plate. at

The fraction collectors 7 are adjacent to the generator C from the side of the nozzles 4. The conveyor 8 serves to return the intermediate fractions to the hopper 1. (Se)

The side edges of the nozzles 4 and the inter-nozzle spaces are covered by the side walls 9 to exclude the suction of air from the atmosphere, which inevitably leads to the failure of the generation. Generator Z is connected to the source of air supply under pressure R.

The method is carried out as follows.

First, the material particles are fed by gravity. To implement this operation - c, a vibrating tray 2 is used. Particles in free fall are acted upon at an acute angle to the vertical by a cascade of flat jets of the generator C (shown in dashed lines), which are in self-oscillating motion. At the same time, if necessary, with the help of the device b for adjusting the volume of the chambers 5, the oscillations of each jet of the entire cascade of jets are achieved in resonance at the first harmonic of the frequency of oscillations, which is evidenced by the maximum quality of separation, or the absence of opening of the cascade of jets (22) (controlled by from known methods, for example, an agrodynamic "flag", a Pitot-Prandtl tube, a pressure sensor, etc.).

After the particles pass through the cascade of jets, the finished fractions are removed. At the same time, intermediate fractions are selected and returned for re-separation using conveyor 8. sl 50 The device works as follows.

The loose mixture from the hopper 1 with the help of a vibrating tray 2 under the influence of gravity enters through a cascade of flat

I" jets (indicated by a dotted line) nozzle 4 in the separating device 7.

When air is supplied under pressure P to the generator Z, the jets of the nozzles 4 interacting in a chain with each other, due to internal positive feedback, enter into self-oscillating motion. Oscillations occur in the vertical plane. The frequency of oscillations of each jet and the entire cascade of jets depends on the value of the volume of the resonance chambers 5 and is set using the device 6.

When the volume increases, the resonant frequency decreases and vice versa. The synchronicity of the nozzles 4 is ensured by the correct ratio of the basic geometric parameters of the generator Z and the volumes of the chambers 5, which is achieved during the device setup process. After separation on the cascade of jets, the particles are lowered into the fraction collectors 7. Final fractions are automatically removed from the "a" collectors, and intermediate fractions are returned to the hopper 1 for re-separation from the "b" collectors with the help of a conveyor 8. b5

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Claims (2)

The formula of the invention of 1. The method of separating a loose mixture in a fluid medium, which includes the gravitational feeding of particles, the aerodynamic monotonically increasing action on them at an acute angle to the vertical by a cascade of flat jets, and the removal of finished fractions, which is characterized by the fact that the aerodynamic action is carried out in the mode of resonance with self-oscillating movement of each jet and the entire cascade of jets at the frequency of the first harmonic of oscillations. 2. A device for separating a loose mixture in a fluid environment, containing a hopper with a vibrating tray, and adjacent to them and installed one under the other and at an acute angle to the vertical, flat nozzles whose caliber, pitch and installation angle increase from top to bottom, and fraction collectors , which differs in that each pair of adjacent nozzles is equipped with a resonance chamber connected to their inter-nozzle space. FO Z. The device according to claim 2, which differs in that the cameras are equipped with a device for adjusting their volume, and the ratio of the caliber of the nozzles to the step of their installation is in the range of 0.2-0.25, while the ratio of the extreme upper and extreme lower nozzle installation angles - 0.65-0.75. name) Official Bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated 1 microcircuits", 2005, M 7, 15.07.2005. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. F) name) 60 b5