RU66983U1 - HIGH FREQUENCY JET GENERATOR FOR SEPARATION OF BULK MIXTURE IN A FLUID - Google Patents

Abstract

The utility model relates to equipment for sorting solid bulk materials in a fluid medium, and more particularly to means for forming directed separating air flows and can be used in automatic devices for cleaning grain, cereals, vegetables, and grass crops.

The high-frequency jet generator for separating granular mixture in a fluid is equipped with a guide frame mounted to cover flat nozzles around the perimeter and made in the form of a pipe segment of rectangular cross section, the ratio of the length, height and width of the passage section of which is accordingly (~ 0.09): 1: (0.3-2.1), while the flat nozzles are fixed in the guide frame so that their input sections are located at the same distance from the plane of the input section of the frame, the value of which does not exceed the length of the cut Single tube of rectangular cross section, and the extreme upper and lower flat nozzle fastened to the guide frame at a distance from its closest surface the magnitude of which exceeds the distance corresponding flat nozzle from the nearest adjacent thereto a flat nozzle. The guide frame has a means of sealing and changing its location.

Description

The utility model relates to equipment for sorting solid bulk materials in a fluid medium, and more particularly to means for forming directed separating air flows and can be used in automatic devices for cleaning grain, cereals, vegetables and grass crops at breeding stations, seed plants, and farmers farms, grain elevators, flour milling and animal feed production.

The prior art method for the separation of bulk mixtures, including the supply of the initial mixture, the impact on the initial mixture located one below the other by air jets, the upper of which is directed horizontally, and the output of the separated fractions, while the air jets, starting from the second from the top, are directed towards the upper jet at an angle, the value of which for each underlying air stream is increased, see. S. SU 1510959, cl. B07B 4/08, published 1989.09.30. The known technical solution allows to improve the quality of separation by maintaining a constant value of the aerodynamic drag force along the entire path of the components of the initial mixture. The disadvantage of this method is the reduction of the horizontal component of the speed of the air jets from the top to the bottom, which creates unequal conditions for processing various fractions of bulk mixtures.

A known method of separating a granular mixture in a fluid medium and a device for its implementation, including gravitational feed of particles and aerodynamic monotonically increasing effect on them at an acute angle to the vertical by a cascade of flat jets in the mode of resonant self-oscillatory motion of each jet and the entire cascade of jets at a frequency

first harmonic of vibrations. In this case, the device includes a hopper with a vibrating tray and flat nozzles adjacent to them and mounted one below the other and at an acute angle to the vertical, whose caliber, step and installation angle increase from top to bottom, and each pair of adjacent nozzles is equipped with a resonant chamber in communication with the inter-nozzle space, in addition, the ratio of the nozzle caliber to the step of their installation is in the range of 0.2-0.25, the ratio of the extreme upper and lower lower nozzle installation angles is 0.65-0.75, see, patent application UA 60254, B07B 4 / 02, published 2003.09.15, or request for zobretenie RU 2004133245, cl. BB07 4/02, published 2006.04.20. In the indicated one and the same known technical solution, an increase in the quality of separation is achieved during multifractional separation of particles of irregular shape. It should be noted that the quality of separation of the granular mixture to a large extent depends on the properties of the starting material, on its moisture content, particle size distribution, density. The specified well-known technical solution was developed for processing predominantly the same type of starting material with its preliminary conditioning, since it does not provide for reinstallation of flat nozzles in case of a forced change in the properties of the starting material.

A device for separating a granular mixture in a fluid containing a hopper and a vibrating tray, a jet generator with flat nozzles of different calibers, installed in series with the flow with increasing variable pitch, acute installation angle, caliber of nozzles from top to bottom, collectors of finished and repeated fractions located under the nozzles, last of which are communicated through a conveying device with a hopper, in which the jet generator is made high-frequency, and nozzles of at least ten are made with walls direct their channels, the length of which increases from top to bottom, wherein the generator is set in front of the nozzles consecutively three sieve, with collections of finished fractions formed two more than collections of repeat separated product fractions, two fractions collection ready installed

near the end of the stream, see, US Pat. RU, cl. B07B 4/02, No. 2270061, published 2006.02.20. The device allows to improve the quality of the separated product, reduce the separation time, increase productivity, as well as reduce the metal consumption and dimensions of the device by optimizing the aerodynamic effects on the particles of the initial product, ensuring accurate distribution of the separated product among the receiving fractions according to weight and shape. This well-known design decision was made as a prototype, as the closest analogue in technical essence, the achieved result and the combination of essential features.

The main element of the prototype device, which improves the quality of the separated product, is a high-frequency jet generator with flat nozzles. Due to the selection of quantity, pitch, acute installation angle, caliber and nozzle length, optimal aerodynamic conditions are achieved for the separation of a particular type of initial bulk mixture. For the separation of a granular mixture with different parameters, and especially a granular mixture of a different type, inevitably there is a need to change the parameters of the generator. The disadvantage of the prototype, therefore, is the impossibility of changing the parameters of the generator without replacing it in each specific case of the device. In addition, such design features of the prototype generator significantly limit the capabilities of the device in terms of regulating its performance. These disadvantages of the prototype narrow the scope of its effective application and do not allow to use for the purposes of this utility model.

The proposed utility model is aimed at achieving a technical result, which is expressed in providing the possibility of simple parameters changing the parameters of a high-frequency jet generator, in particular, the acute angle of nozzles, directly on a specific device, while maintaining the high quality of processing of the separated product and other positive properties of the prototype. The end result

This technical result is expressed in simplifying the process of using a high-frequency jet generator, expanding the field and increasing the efficiency of its application by providing the possibility of processing bulk materials with various mechanical properties.

A positive result is achieved in that the high-frequency jet generator for separating the granular mixture in the fluid, containing flat nozzles of different calibres installed with increasing variable pitch, acute installation angle to the vertical, caliber and length of the walls of the guide channels of the nozzles from top to bottom, differs from the prototype in that, it is equipped with a guide frame installed with the possibility of covering around the perimeter of flat nozzles and made in the form of a piece of pipe of rectangular cross section, the ratio of the length, height and width of the passage whose cross section is (~ 0.09): 1: (0.3-2.1). Flat nozzles are fixed in the guide frame in such a way that their input sections are located at the same distance from the plane of the input section of the frame, the value of which does not exceed the length of the pipe segment of rectangular section. The extreme upper and lower flat nozzles are fixed in the guide frame at a distance from its nearest surface, the magnitude of which exceeds the distance of the corresponding flat nozzle from the nearest neighboring flat nozzle.

Preferably, in at least one flat nozzle, the top and bottom walls of the guide channels are made of the same length and the caliber uniformly changing in the direction of movement of the gas stream. Optimal from the point of view of achieving the indicated technical result is equipping the high-frequency jet generator with means for sealing the guide frame, made in the form of an elastic seal, reinforced around the perimeter of the guide frame. In all cases of implementation of a high-frequency jet generator, it is advisable to equip it with a means of changing the location of the guide frame.

A high-frequency jet generator for separating a granular mixture in a fluid is a complex gasdynamic system that controls the air flow directed to interact with the particles of the granular mixture. Each flat nozzle of the generator is a unique element in terms of its geometric parameters. Moreover, the relative position of the flat nozzles and their number tell the generator individual properties that basically determine the characteristics of the installation as a whole. The separation quality of a particular granular mixture in this way mainly depends on the optimal selection of the characteristics of the jet generator. The ability to change the characteristics of the jet generator in one installation provides ample opportunity for unification and improve the quality of separation. The design of the jet generator according to the present utility model provides the ability to change the acute angle of installation to the vertical at the same time of all flat nozzles, as well as the effective length of the separation chamber by changing the location and orientation of the entire system of flat nozzles. These parameters are important for selecting the characteristics of the jet generator, and their change even within narrow limits (several degrees in angle and centimeters in longitudinal movement) can have a decisive influence on ensuring the quality of separation. The presence of the guide frame, which is the holder of the system of flat nozzles, allows you to convert the jet generator into a standalone easily replaceable and movable unit, which, together with the appropriate means of changing the location and sealing the guide frame, provides the functions of regulating its parameters and preserving the properties of the stationary unit. The implementation of the guide frame in the form of a segment of a pipe of rectangular cross-section makes it easy to mount the jet generator in the flow part of the duct while maintaining the geometry of the flow part of the latter. The fundamental parameter of the jet generator, which determines the effective residence time of the particles of the granular mixture in

separation chamber and on which all other parameters depend, is the height. Therefore, the height of the pipe segment of a rectangular section of the guide frame is taken as the base unit. The practical value of the height of the guide frame is about one thousand millimeters. The length of a pipe segment of a rectangular section of the guide frame directly depends on the height of the passage section and is approximately 0.09 from it. With a decrease in the relative length, the stability of the guide frame under the pressure of a gas jet is lost, and with an increase, significant turbulization occurs at the extreme angles of adjustment of the generator. The accuracy of the ratio of height and length falls within the technological tolerance. The width of the bore of the guide frame determines the performance of the installation. However, with a too narrow (less than 0.3 height) guide frame, the effect of the wall layer on the separation quality is manifested, when a large mass of particles of the granular mixture begins to interact with the side walls of the separation chamber. If the guide frame is too wide (more than 2.1 heights), an extra powerful air blower fan is required, and there are also problems with ensuring the uniformity of the gas stream across the width of the flat nozzle and the supply of the bulk mixture from the loading hopper. Within the stated ratio of the height and width of the passage section of the guide frame, namely 1: (0.3-2.1), wide possibilities for changing productivity are provided, from several hundred kilograms per hour to several tens of tons per hour.

Of great importance is the depth of installation of the flat nozzles in the guide frame, which is determined by the distance from the plane of the input section of the frame to the input sections of the flat nozzles. Firstly, the specified distance should be the same for all flat nozzles to ensure the same gas-dynamic conditions of flow entry in the guide channels and simplify the design. Secondly, the specified distance should not exceed the length of the guide frame since otherwise flat

the nozzles are completely moved outside the internal volume of the guide frame, and the jet generator itself is unreasonably increasing in size, which complicates its installation. The quality of separation and fine purification of the granular mixture in a fluid medium, as well as the stability of the device, to a large extent depends on the nature of the flow of air flow in the jet generator. In the event of disruption of the air flow, the formation of zones of turbulence or stagnant zones, a sharp decrease in operating efficiency occurs. These phenomena occur mainly due to the interaction of the air flow with the structural elements of the device whose surface is located in the area of the air flow. To exclude the possible interaction of a gas jet emerging from the extreme upper and lower flat nozzles with the upper and lower walls of the gas duct at maximum deviations (movements) of the guide frame, these flat nozzles are separated from these walls by a value of the characteristic distance, which are the distances to the nearest adjacent flat nozzle . If it is necessary to increase the number of flat nozzles or a variable pitch between them, for example, to increase the number of emitted fractions, the length of the upper and lower walls of the guide channels of one or more flat nozzles can be made different. This problem can also be solved by performing these guide channels uniformly changing in the direction of movement of the gas stream.

Thus, all the hallmarks of a high-frequency jet generator for separating a granular mixture in a fluid are distinguished from the prototype in order to obtain a technical result, namely, simplifying the process of using a high-frequency jet generator, expanding the field and increasing its efficiency by providing the possibility of processing bulk materials with various mechanical properties.

The technical solution, characterized by the described combination of essential features, is new and industrially applicable.

The technical solution is illustrated by drawings.

Figure 1 shows a General view of the separating device in which a high-frequency jet generator is installed to separate the granular mixture in a fluid medium; figure 2 - high-frequency jet generator for the separation of granular mixture in a fluid medium, view a in figure 1; figure 3 - high-frequency jet generator for separation of the granular mixture in the fluid in the context of BB in figure 2; figure 4 - section of a flat nozzle with different lengths of the upper and lower walls of the guide channels and a uniformly changing caliber, increased node I in figure 3; 5 is a means of sealing the guide frame, increased node II in figure 3.

A device for which a high-frequency jet generator 1 is specifically designed for separating a granular mixture in a fluid includes a feed hopper 2, a separation chamber 3, and collectors 4 of finished fractions. The input part of the high-frequency jet generator 1 is connected to a fan of the air blower 5. In the upper part of the rear wall of the separation chamber 3, an opening 6 is made for the removal of air flow and volatile fractions from the separation chamber 3. The generator 1 consists of a guide frame 7 and flat nozzles 8. The guide frame 7 is made in the form of a pipe segment of rectangular cross section, the dimensions of which are presented in a dimensionless form. The height of the bore of the guide frame 7 is conventionally assumed to be equal to unity, and 1.0 is indicated in the figure. The length of the guide frame 7 is about 0.09 of its height and ~ 0.09 is indicated on the figure. The width of the passage section of the guide frame 7 is defined in the range from 0.3 to 2.1 of its height and in the figure is designated 0.3-2.1. Inside the guide frame 7 there is a partition 9 in which parallel horizontal slots are made to accommodate the flat nozzles 8. The flat nozzles 8 are installed so that their inlet sections are located at the same distance from the plane of the input section of the guide frame 7 (in figure 3 is indicated by the letter h) value which does not exceed the length of the guide frame 7. Extreme upper flat nozzle 8

is fixed from the guide frame 7 at a distance t _{1 the} value of which exceeds the distance (the figure 3 denotes t ₂ ) to the nearest adjacent flat nozzle 8. The lowermost flat nozzle 8 is fixed from the guide frame 7 at a distance t _{4 the} value of which exceeds the distance (indicated in figure 3 by t ₃ ) to the nearest adjacent flat nozzle 8. In addition, the flat nozzles 8 are fixed relative to each other at different distances (in figure 3 are indicated t ₂ and t ₃ ) with increasing variable pitch between them from above in bottom. Each flat nozzle 8 has its own distinct acute angle (α is indicated in FIG. 4) to the vertical installation, gauge (d is indicated in FIG. 3) and the length (L is indicated in FIG. 3) of the walls 10 of the guide channels. The parameters α, d, L of the flat nozzles 8 are discretely changed in the direction of increase from the upper nozzle to the lower. The figure 3 shows the high-frequency jet generator 1, in which the length of the upper and lower walls 10 of the guide channels in each of the five flat nozzles 8 is made the same, and the caliber of each of the five flat nozzles 8 is made unchanged, however, a design is possible (figure 4) in which at least one of the flat nozzles 8 has walls 10 of the guide channels of various lengths and / or caliber uniformly changing in the direction of movement of the gas stream. The high-frequency jet generator 1 can be equipped with a means of sealing the guide frame 7, which is made in the form of an elastic, for example rubber seal 11, fixed around the perimeter of the guide frame 7. The guide frame 7 is predominantly mounted with the possibility of movement with two degrees of freedom. The possibility of changing the installation angle of the guide frame 7 (in figure 1, the possible angular movements of the guide frame 7 are conventionally indicated by rounded arrows) and the possibility of reciprocating movement of the guide frame 7 in the direction of the gas jet (in figure 1, the possible reciprocating movements of the guide frame 7 are conventionally indicated by straight lines arrows) provided by special

means for changing the location of the guide frame 7, made in the form of a swivel 12.

The device operates as follows.

Depending on the required performance, type and condition of the granular mixture, a high-frequency jet generator 1 of the appropriate size and characteristics is installed in the device. The device should be equipped with a set of high-frequency jet generators 1. The bulk mixture to be separated, for example, grain is poured into the loading hopper 2. When the device is connected to the power line, a uniform flow of particles of the granular mixture into the separation chamber 3 and the fan blower 5 of the jet generator 1. The high-frequency jet the generator 1, due to a set of flat nozzles 9, provides a uniform and directed air flow to the separation chamber 3. The air flow picks up the flow of grain freely falling from the loading hopper 2. Thus, there is a counter-lateral movement of the gas stream and particles of the granular mixture, which leads to the weighing of the latter. As a result of the impact on the bulk mixture of the scanning cascade of flat air jets, the particles of the separated material are separated into fractions that differ in density and aerodynamic characteristics. More dense and streamlined particles fall into the zone of the first collector 4, and less dense with a developed surface are discarded to the subsequent collectors 4. Thus, stones and heavy impurities enter the zone of the first collector 4, the second - sown grain, the third - food grain, the fourth and the fifth - feed grain, the next - non-commodity fractions of the granular mixture. The fractions of the separated bulk mixture are accumulated in the respective collections 4 and periodically unloaded from them for further processing. Volatile and dusty fractions are carried away by the air flow and are taken out of the separation chamber 3 through the opening 6 to divert the air flow and volatile fractions. With unsatisfactory quality of separation of the granular mixture, carry out

fine tuning of the high-frequency jet generator 1 by changing the installation angle of the guide frame 7 and moving it in the direction of the gas jet by acting on the swivel joint 12 of a special means of changing the location of the guiding frame 7. If, as a result of the fine-tuning of the high-frequency jet generator 1, it is not possible to achieve a satisfactory quality of loose bulk mixture, stop the device and change the high-frequency jet generator 1, and then restart at troystvo and repeated fine adjustments high jet generator 1 by the above-described. Selective selection and tuning of a high-frequency jet generator 1 allows to increase the accuracy of separation of product fractions up to 98-98.5% i.e. when the content of substandard material in the fraction does not exceed 1.5-2.0%. The change of high-frequency jet generator 1 is also carried out if necessary, to reduce or increase productivity.

The above-described example implementation of the device is given only for the purpose of explaining the technical solution. Specialists in this field can improve the generator and / or implement alternatives within the essence of this utility model, as reflected in the description and drawings.

A high-frequency jet generator for separating a granular mixture in a fluid is effective when used in precise multifraction separation units for a granular mixture, for example, simple and complex crops for breeding purposes, as well as in the processing and preparation of seeds for sowing.

Claims (5)

1. A high-frequency jet generator for separating a granular mixture in a fluid, comprising flat nozzles of various calibers installed with increasing variable pitch, an acute installation angle to the vertical, gauge and length of the walls of the guide channels of the nozzles from top to bottom, characterized in that it is provided with a guide frame, installed with the possibility of covering around the perimeter of flat nozzles and made in the form of a segment of a pipe of rectangular cross section, the ratio of the length, height and width of the passage section of which is respectively (~ 0.09): 1 : (0.3-2.1), while the flat nozzles are fixed in the guide frame in such a way that their input sections are located at the same distance from the plane of the input section of the frame, the value of which does not exceed the length of the pipe segment of rectangular cross section, and the outermost and the lower flat nozzles are fixed in the guide frame at a distance from its nearest surface, the magnitude of which exceeds the distance of the corresponding flat nozzle from the nearest neighboring flat nozzle. 2. The high-frequency jet generator according to claim 1, characterized in that the length of the upper and lower walls of the guide channels of at least one flat nozzle is made the same. 3. The high-frequency jet generator according to claim 2, characterized in that the caliber of the at least one flat nozzle is made uniformly changing in the direction of movement of the gas stream. 4. The high-frequency jet generator according to claim 3, characterized in that it is provided with means for sealing the guide frame, made in the form of an elastic seal, reinforced around the perimeter of the guide frame. 5. The high-frequency jet generator according to any one of claims 1 to 4, characterized in that it is provided with means for changing the location of the guide frame.