RU2620819C1 - Hydraulic classifier - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: hydraulic classifier comprises a casing, a screening device set along the casing, branch pipes for water supply and fine fraction removal set at the casing corners being opposite to each other as per diagonal in its longitudinal section, branch pipes for suspension supply and removal set at the other casing corners being opposite to each other as per diagonal in its longitudinal section, a vibrator, the screening device consists of sieves coupled pairwise along the perimeter by a shell. Dryer device is made of united in pairs around the perimeter of the sidewall sieve. The branch pipes for suspension supply and removal are communicated with the inner space of evey pair of sieves. The vibrator is coupled with the screening device. Flexible pipelines are connected to the branch pipe for suspension supply, divergent nozzles with curvilinear spiral-like guides at their inner surface are installed on the pipelines in tiers within the half of the suspension chamber height and ar located in the inner space of every pair of sieves interconnected by resilient plates. Side end faces of the suspension chambers are enclosed by mesh. The vibrator is equipped with a drive with adjustable rotation speed, and speed controller is associated with pressure regulator, coupled with pressure sensor, positioned in the water-supply tube. The pressure regulator comprises interconnected comparators and setting units, electronic and magnetic amplifiers and a nonlinear connection unit. The speed controller is made as a unit of powder electromagnetic clutches. Curved helical guides located on the inner surface of the expanding nozzle, covered on the outside of the cavity glassiness nano-like film of tantalum oxide.

EFFECT: increase in the productivity and effectiveness of the classification.

5 dwg

Description

The invention relates to the processing of fibrous materials and can be used in the asbestos and pulp and paper industry.

Known hydroclassifier (see RF patent No. 2189979, IPC B03B 5102, publ. 09/20/2002, bull. No. 26) comprising a housing, a screening device located along the housing, installed at opposite angles of the housing in its longitudinal section of the water inlet and outlet nozzles fine fractions located at other diagonally opposite corners of the body in its longitudinal section of the inlet and outlet of the suspension, the vibrator, the screening device is made of sieves connected in pairs along the perimeter, while the inlet pipes and the outlet of the suspension is associated with the internal space of each pair of screens, and the vibrator is connected to a screening device, while flexible pipelines are attached to the suspension supply pipe, on which expanding nozzles with curved spiral guides on their inner surface are installed in tiers within half the height of the chamber for the suspension and are located in the inner space of each pair of screens, interconnected by elastic plates, and the side ends of the suspension chambers are fenced.

Known hydroclassifier (see RF patent No. 2553127, publ. 06/10/2015, bull. No. 16), comprising a housing located along the housing of a screening device installed at opposite diagonally angles of the housing in its longitudinal section of the water inlet and outlet of the fine fraction, located at other diagonally opposite corners of the housing in its longitudinal section, the inlet and outlet pipes of the suspension, the vibrator, sieving device is made of sieves connected in pairs along the perimeter, while the inlet and outlet pipes with the suspensions are associated with the inner space of each pair of screens, and the vibrator is connected to a screening device, while flexible pipelines are attached to the suspension supply pipe, on which expanding nozzles with curved spiral guides on their inner surface are installed in tiers within half the height of the chamber for the suspension and are located in their the inner space of each pair of screens connected by elastic plates, and the side ends of the suspension chambers are fenced with a mesh, while the torus is equipped with a drive with a speed controller, and the speed controller is connected to a pressure controller connected to a pressure sensor located in the water supply pipe, while the pressure controller contains interconnected comparison and reference units, electronic and magnetic amplifiers and a nonlinear communication unit, in addition , the speed controller is made in the form of a block of powder electromagnetic couplings.

The disadvantage is an increase in energy consumption during long-term operation, due to an increase in the hydraulic resistance of the expanding nozzles due to the sticking of suspensions on the outer sides of the curved spiral-shaped guide particles, which leads to a decrease in the cross section of the expanding nozzles and, as a consequence, the need to increase the pump power for feeding the suspension.

The technical task of the invention is to maintain normalized energy consumption for the processing of fibrous materials during long-term operation by preventing the increase in hydraulic resistance of the expanding nozzles by eliminating the buildup of suspension particles on the outside of the curved spiral guides.

The technical result is achieved by the fact that the hydroclassifier includes a housing located along the housing of a screening device installed at opposite diagonally angles of the housing in its longitudinal section of the water inlet and outlet small fractions located at other opposite angles of the housing in its longitudinal section of the inlet and suspension release, vibrator, sieving device is made of sieves connected in pairs along the perimeter along the perimeter, while the inlet and outlet pipes of the suspension with are connected with the internal space of each pair of screens, and the vibrator is connected to a screening device, while flexible pipelines are attached to the suspension supply pipe, on which expanding nozzles with curved spiral guides on their inner surface and located in the inner surface are installed in tiers within half the height of the suspension chamber the space of each pair of screens connected by elastic plates, and the side ends of the suspension chambers are fenced with a grid, while the vibrator is equipped with a drive with a speed controller, and the speed controller is connected to a pressure controller connected to a pressure sensor located in the water supply pipe, while the pressure controller contains interconnected comparison and reference units, electronic and magnetic amplifiers and a nonlinear communication unit, in addition, a controller the rotation speed is made in the form of a block of powder electromagnetic couplings, while curved spiral guides located on the inner surface of the expanding nozzles are covered with the other side of the cavity with a glassy nanosimilar tantalum oxide film.

In FIG. 1 shows a hydroclassifier, a general view, and FIG. 2 is a transverse section AA, in FIG. 3 is a perspective view of a flexible conduit with expanding nozzles, and FIG. 4 is a scan of the inner surface of expanding nozzles with curved spiral guides, in FIG. 5 is a profile of curved spiral guides with tantalum oxide coated on the outside in the form of a glassy nanosimilar film.
The hydroclassifier includes a housing 1, a screening device 2 located along it, and a vibrator 3 for transmitting vibration to the screening device 2. At the diagonally opposite corners of the body 1, a water inlet 4 and a small fraction outlet 5 are installed in its longitudinal section. Other opposite diagonally angled corps 1 in its longitudinal section are the pipe 6 of the input of the suspension and the pipe 7 of the output of the suspension. The screening device 2 is made of sieves 9 connected in pairs along the circumference of the circumference 8, forming chambers 10 for suspension. The vibrator 3 is connected to a screening device 2 for transmitting vibration to the coupled sieves 9 located inside the housing 1. The drive 11 is also connected to the vibrator 3, and an oil seal 13 is installed on the side wall 12 of the housing 1. With a large number of sieves 9 connected in pairs, additional a vibrator 3 on the opposite side wall 12. Flexible pipes 14 are attached to the suspension input pipe 6, on which expandable nozzles 15 with curvilinear spiral guides 16 are installed on their inner surface ty. The ends of the slurry chambers 10 are fenced with a grid 17. The coupled sieves 9 are interconnected by elastic plates 18. The vibrator 3 is equipped with a drive 11 with a speed controller 19 in the form of a block of powder electromagnetic couplings, and a speed controller 19 is connected to a pressure controller 20, connected by a pressure sensor 21 located in the pipe 4 of the water inlet, while the pressure regulator 20 contains interconnected blocks 22 and reference 23, electronic 24 and magnetic 25 amplifiers and a non-linear feedback block 26.

The cavities 27 of curved spiral guides 16 located on the inner surface 28 of the expanding nozzles 15 are coated on the outside 29 with tantalum oxide in the form of a glassy nanosimilar film 30.

The hydroclassifier works as follows. When moving the suspension along curved spiral-shaped guides 16 of the expanding nozzles 15 in the chamber 10, fractions, especially small ones, of fibrous material adhere to the outer sides of 29 cavities 27 and form jams in them. As a result, the moving flow of the suspension moves along the inner surface 28 of the expanding nozzles 15 straight-through without swirling due to clogging of the cavities 27 with an adherent classified material, which sharply reduces the quality of the finished product. When the outer side 29 is coated with a glass-like nano-like film of tantalum oxide 30, the suspension, including its small fractions, glide along it (see, for example, Litvinova V.A., Savruk E.N. Nanosized films of tantalum oxide obtained by ion plasma method // Proceedings of the regional scientific-practical conference "Modern problems and achievements of agricultural science in animal husbandry, crop production and the economy." - Tomsk: TEKhI NSAU - issue 12 - 2010 - p. 299 - 301) without sticking and, accordingly, without consolidation and creating congestion in the cavities 27. Consequently, turbulization of the boundary layer is ensured with the elimination of the near-wall effect and the process of high-quality hydroclassification of fibrous materials is supported during long-term operation.

 The power of the actuator 11 of the vibrator 3 is selected for the case of maximum pressure in the water inlet 4, which is detected by the pressure sensor 21. However, during the operation of the hydroclassifier, the concentration of asbestos fibers changes to a lower side and the hydroclassification process will require a decrease in power to the actuator 11 of the vibrator 3, and while its power remains constant, i.e. there is an unreasonable waste of energy. In the proposed technical solution, the rotation speed of the actuator 11 of the vibrator 3 is controlled, which allows to optimize energy consumption by reducing them depending on the concentration of asbestos fibers in the suspension. So with a decrease in the number of classified asbestos fibers in suspension, the amount of incoming water into the pipe 4 decreases with a decrease in pressure in it, which is detected by the pressure sensor 21 and the signal supplied to it by the pressure regulator 20 becomes larger than the signal of the task unit 23, and the output of the comparison unit 22, a signal of negative polarity appears, which is fed to the input of the electronic amplifier 24 simultaneously with the signal of negative nonlinear coupling of the block 26. Due to this, the electronic amplifier 24 eynost actuator 11 gidroklassifikatora characteristics.

The signal from the output of the electronic amplifier 24 is fed to the input of the magnetic amplifier 25, where it is amplified by power, rectified and fed to the speed controller in the form of powder electromagnetic couplings. The negative polarity of the signal of the electronic amplifier 22 causes a decrease in the excitation current at the output of the magnetic amplifier 25. As a result, the power taken from the drive 11 is reduced, i.e. energy is saved when the water supply to the pipe 4 is normalized. An increase in the concentration of asbestos fibers in the suspension leads to an increase in the water supply through the pipe 4, and the pressure in it increases, which is detected by the pressure sensor 21, and the signal coming from it to the pressure regulator 20 becomes smaller than the signal of the reference unit 23, and the output of the comparison unit 22 will receive a signal of positive polarity, which is fed to the input of the electronic amplifier 24 simultaneously with the signal of negative nonlinear feedback of the block 26 The signal from the output of the electronic amplifier 24 is fed to the input of the magnetic amplifier 25, where it is amplified by power, rectified and fed to the speed controller 19 in the form of a block of powder electromagnetic couplings.

The positive polarity of the signal of the electronic amplifier 24 causes an increase in the excitation current at the output of the magnetic amplifier 25. As a result, the selected power increases, approaching the nominal one for the case of maximum pressure in the pipe and water inlet. Therefore, the hydroclassifier, working in the mode of smooth change of power on the drive 11 by means of a speed controller of rotation 19 under the condition of different concentrations of asbestos fibers in the suspension, provides energy savings.

For each of the operating modes of the hydroclassifier, determined by the concentration of asbestos fibers, the following is carried out.

A suspension containing, for example, asbestos fibers of various lengths, is fed into the suspension chambers 10, each of which consists of two sieves 9. Wash water is supplied through the pipe 4. The mutual opposite location of the pipe 6 of the input of the suspension and the pipe 4 of the input of water, as well as the pipe 7 of the output of the suspension and the pipe 5 of the output of the fine fraction, provides the movement of the suspension and wash water in countercurrent. By means of a vibrator 3 and a drive 11, the screens 9 of the screening device 2 are vibrated relative to the side walls 12 of the housing 1 in a horizontal plane transverse to the movement of the separated suspension flows. Due to this, through the sieve 9 there are flows of the suspension with a fine fraction of fibers into the housing 1 and the wash water in the chamber 10 for the suspension. Thus, the classification of fibrous materials. The exit of the suspension through the expanding nozzles 15 with curved spiral guides 16 into the chambers 10 for the suspension, installed on flexible pipelines in tiers within half the height of the chamber 10 for the suspension on the flexible pipelines 14, creates a swirling flow and wave motion over its entire live section. In this case, the wave motion of the suspension has a vibrational effect on the sieves 9, increases the flow rate of the suspension, eliminates the occurrence of a wall effect, improves the quality of classification of fibrous materials. The elastic plates 18 make it possible to transfer vibration to all pairs of screens 9 without installing additional vibrators 3. The lateral ends of the suspension chamber 10 enclosed by a mesh exclude mixing of large and small fractions in the housing 1, which also improves the quality and classification efficiency of fibrous materials.

The increased vibration of the screening devices due to the swirling and wave motion of the suspension ultimately leads to intensive mixing of the working medium, increase the speed of its movement, eliminates the occurrence of a wall effect, and in combination with the complete separation of the suspension fractions increases the hydroclassifier productivity and the efficiency of classification of fibrous materials.

The originality of the invention lies in the fact that the coating on the outside of the cavities of curvilinear spiral guides located on the inner surface of the expanding nozzles with a glassy nanosimilar tantalum oxide film eliminates the sticking of finely dispersed contaminants, as well as fine fractions of the fibrous classified material, and ensures long-term production of high-quality finished product

Claims (1)

A hydroclassifier, including a housing, a screening device located along the housing, installed at opposite diagonal corners of the housing in its longitudinal section of the water inlet and outlet small fractions, located at other opposite diagonal corners of the housing in its longitudinal section of the intake and outlet of the suspension, vibrator, the sifting device is made of sieves connected in pairs along the perimeter by a perimeter, while the inlet and outlet pipes of the suspension are interfaced with the inner space of each th pair of sieves, and the vibrator is connected to a screening device, while flexible pipelines are attached to the suspension supply pipe, on which expanding nozzles with curved spiral guides on their inner surface and are located in the inner space of each pair of sieves are installed in tiers within half the height of the chamber for the suspension interconnected by elastic plates, and the side ends of the suspension chambers are fenced with a mesh, while the vibrator is equipped with a drive with a speed controller I, and the speed controller is connected to a pressure controller connected to a pressure sensor located in the water supply pipe, while the pressure controller contains interconnected comparison and reference units, electronic and magnetic amplifiers and a nonlinear communication unit, in addition, the speed controller is made in a block of powder electromagnetic couplings, characterized in that the curved spiral guides located on the inner surface of the expanding nozzles are coated on the outside of the glass cavity a nano-like tantalum oxide film.

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