RU2610632C1 - Vortical evaporation-drying chamber with inertial nozzle - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: vortical evaporation-drying chamber with inertial nozzle contains placed in the common housing the evaporative and drying chambers with the gas supply and discharge pipelines, as well as the filtering heat-exchanger, implemented as a nozzle from boiling bed of inertial bodies. The sprinkler is situated above this nozzle. The sprinkler is designed as a header with control throttle of primary solution supply, rotating on bearings. Exhaust ash-laden gases are pre-treated in acoustic plant, and then gas flows to the cyclone with a silo, where the main part of gas-entrained dry material is released. The final cleaning of gases is taken place in sleeve filter with silo. The nozzles are designed in the form of acoustic nozzles. The resonator is designed in the form of at least one spherical cavity, or the resonator may be designed in the form of toroidal cavity. The inertial nozzle is designed in the form of cylindrical ring, on the side, inner and outer surfaces of which there is screw thread, made in the opposite directions, or in the form of a ball, on the surface of which there are non-through holes of hemispherical shape, or in the form of a ring, on the outer surface of which the helical surface is made in the form of a plate screw, or in the form of at least a three-bladed propeller.

EFFECT: increase of the drying performance.

6 dwg

Description

The invention relates to techniques for drying solutions, floats, suspensions and obtaining granules of various substances and can be used in microbiological, food, chemical and other industries.

The closest technical solution to the claimed object is a dryer according to the patent of the Russian Federation No. 2328664, F26B 17/10, 1975, containing the evaporating and drying chambers and gas supply and exhaust pipelines located in a common housing, as well as a filter-heat exchanger made in the form of a nozzle made of a fluidized bed of inert bodies, over which a sprinkler is located (prototype).

The disadvantage of the prototype is the relatively low productivity of drying the final product due to the insufficiently high degree of spray solutions.

The technical result is an increase in drying performance.

This is achieved by the fact that in a vortex evaporation-drying chamber with an inert nozzle containing an evaporation and drying chambers located in a common housing, and gas supply and exhaust pipelines, as well as a filter-heat exchanger made in the form of a nozzle from a fluidized bed of inert bodies, above which sprinkler, sprinkler is made in the form of a collector rotating in bearings with a control throttle for supplying the initial solution, and the exhaust dusty gases are subjected to preliminary acoustic treatment in acoustic installation, after which the gas flow is directed to the cyclone with the hopper, where the main part of the dry material carried away by the gases is released, and the final cleaning of the gases takes place in a bag filter with the hopper, the nozzles being made in the form of acoustic nozzles, the resonator is made in the form of at least one , a spherical cavity located in the end wall of the housing facing the distribution head, and the spherical cavity is connected by a calibrated hole with a gap between the vertical hole in the end wall and the housing and the rod of the distribution head, and in a section perpendicular to the axis of the rod, the gap has an annular section, and the distribution head is made in the form of a housing with a cover in the form of truncated cones connected by large bases, and a collector in the form of a cylindrical cavity connected by an annular a channel formed by the outer cylindrical surface of the hollow rod and holes of the same diameter coaxial with it, made respectively in the cover and body of the distribution head With at least three uniformly arranged along the circumference and perpendicular to the axis of the rod to exit channels solution and the cut holes located on the conical surface of the dispensing head cover, the slope of which determines the angle of the root flame sprayed solution.

In FIG. 1 shows a vortex evaporation-drying chamber with an inert nozzle; FIG. 2 is a general view of a pneumatic acoustic nozzle; FIG. 3-6 are diagrams of an embodiment of an inert nozzle 4 located in a heat exchanger filter.

The vortex evaporation-drying chamber with an inert nozzle contains an evaporation chamber 1 (Fig. 1) located in a common housing and a drying chamber 2 separated by a partition 3. The evaporation chamber 1 is a cylinder and is located above the cylindrical drying chamber 2. In the evaporation chamber there is a filter a heat exchanger made in the form of a nozzle 4 from a fluidized bed of inert bodies, over which a sprinkler 5 is located, which is a collector rotating in bearings 12 with a control choke 13 for supplying the initial solution. The implementation of the sprinkler 5 rotating allows you to intensify heat and mass transfer.

In order to avoid wear of inert bodies, the nozzle is limited by grids 6. The cylindrical drying chamber 2 is equipped with gas supply tangential pipelines 7 and a discharge pipe 8 located inside the drying chamber, over which a protective umbrella 9 is placed. In the drying chamber there are also acoustic nozzles 10 (Fig. 2). For unloading the dried material, an unloading device is provided in the lower part of the drying chamber 2. The discharge pipe 11 is designed to discharge the gas suspension formed during the drying process. Exhaust dusty gases are subjected to preliminary acoustic treatment in an acoustic installation 14, after which the gas stream is directed to a cyclone 15 with a hopper, where the bulk of the dry material carried away by gases is released, and the final gas purification takes place in a bag filter 16 with a hopper.

The acoustic nozzle (Fig. 2) contains a hollow body 17 with walls formed by a conical and end surfaces with a resonator 25 and a cavity 21 for a spraying agent entering through the nozzle 19 into the manifold 18 connected through openings 20 to the cavity 21, which is made in the form of a truncated cone with a larger and smaller base.

On the hollow cylindrical rod 23, rigidly connected with the housing 17, a distribution head 32 is installed for supplying the initial solution through the nozzle 22, while between the rod 23 and the housing 17 from the side of the smaller base of the truncated cone forming the cavity 21, there is an annular gap 24. Resonator 25 can be made in the form of at least one spherical cavity located in the end wall of the housing 17 facing the distribution head 33, and the spherical cavity is connected by a calibrated hole 26 with a gap 24 between a vertical hole in the end wall of the housing 17 and the rod 23 of the distribution head 33. In a section perpendicular to the axis of the rod 23, the gap 24 has an annular cross section, and the distribution head 33 is made in the form of a housing 30 with a cover 29 in the form of truncated cones connected by large bases. A manifold 31 in the form of a cylindrical cavity is located in the housing of the distribution head 33, connected by an annular channel 34 formed by the outer cylindrical surface of the hollow rod 23 and holes of the same diameter coaxial with it, made respectively in the cover 29 and the housing 30 of the distribution head 33, with at least three channels 28, evenly spaced around the circumference and perpendicular to the axis of the rod 23, for the exit of the solution. A cut of the openings of the channels 28 is located on the conical surface of the cover 29 of the distribution head 33, the angle of inclination of which determines the root angle of the spray plume.

The resonator 25 can be made in the form of a toroidal cavity (not shown), the axis of which is located coaxially with the rod 23 of the distribution head 33, and its cavity is connected by at least one calibrated hole 26 with an annular gap between the vertical hole in the end wall of the housing 17 and a rod 23 of the distribution head 33. The channel for the exit of the solution can be made in the form of a radial annular gap (not shown) lying in a plane perpendicular to the axis of the rod 23 of the distribution head 33, and it would be formed in the cover 29 by means of plates 27 rigidly attached to the shaft 23, perpendicular to its axis and connected with lid 29, at least three fasteners 35 to form a radial annular gap.

Vortex evaporation-drying chamber with an inert nozzle operates as follows.

The source material to be dried through the sprinkler 5 is fed to the nozzle 4 from inert bodies forming a layer under the action of gases leaving the drying chamber 2 through a pipeline 8. On the nozzle 4, the starting material is partially evaporated. In addition, the nozzle 4 performs a number of side functions: reduces the temperature of the exhaust gases, acts as a filter. When inert bodies are used as nozzles, the heat exchange surface can be increased. Since the nozzle 4 is constantly irrigated with the starting material, clogging of it with the dried material is prevented.

One stripped off heated source material accumulates on the partition 3. Using compressed air nozzles 10 one stripped off heated source material is sprayed into the drying chamber 2.

In the drying chamber 2, the material is dried, and the dried material is discharged from the installation through an unloading device. The spent heat carrier (exhaust gases), for example hot air, together with a part of the finely divided dried material enters the pipeline 8, from where the exhaust gases enter the evaporation chamber 1, penetrate the nozzle 4, creating a fluidized bed of inert bodies and heating the source material, and leave the installation through the pipeline 11. Exhaust dusty gases are subjected to preliminary acoustic treatment in acoustic installation 14, the optimal parameters of which for sound processing of fine dust are: Wen sound pressure of 140 dB or more, the frequency of the vibrational motion of 900 Hz, the concentration of dust in the air stream at least 2 g / m ^3, while insonation 1.5 ... 2 seconds, after which the gas stream is directed into the cyclone hopper 15, where principal allocated part of the dry material carried away by the gases, and the final cleaning of the gases takes place in a baghouse 16 with a hopper. The ingress of fine material into the evaporation chamber 1 is prevented by a safety umbrella 9.

The acoustic nozzle for spraying liquids works as follows.

A spraying agent, for example air, is supplied through a nozzle 19 to a manifold 18 connected through openings 20 to a cavity 21, which is made in the form of a truncated cone. From the cavity 21, air is directed into the annular gap 24 between the rod 23 and the housing 17, where it encounters a resonator 25 made in the form of a spherical cavity connected to the gap 24 by means of a calibrated hole 26. As a result of the passage of the resonator 25 by a spray agent (for example, air ) in the latter, pressure pulsations arise, creating acoustic vibrations, the frequency of which depends on the parameters of the resonator. Acoustic vibrations of the spraying agent contribute to finer atomization of the solution supplied to the distribution head 33 through the hollow rod 23, from which the solution is supplied in the form of a liquid film blocking the output of the spraying agent from the sound vibration generator formed by the resonator 25. This film is crushed by acoustic air vibrations into small drops, as a result of which a torch of a sprayed solution with air is formed, the root angle of which is determined by the angle of inclination of the horse eskoy surface of the lid 29 of the dispensing head 33.

It is possible to perform the form of an inert nozzle 4, located in the heat exchanger filter, in the form of a cylindrical ring (Fig. 3), on the lateral, internal and external surfaces, which are screwed (not shown in the drawing) in opposite directions.

It is possible to perform the form of an inert nozzle 4 located in the heat exchanger filter (Fig. 4) in the form of a ball on the surface of which through holes are made through a hemispherical shape (not shown in the drawing).

It is possible to perform the form of an inert nozzle 4 located in the heat exchanger filter (Fig. 5) in the form of a ring, on the outer surface of which a helical surface is made like a plate auger.

It is possible to carry out the form of an inert nozzle 4 located in the heat exchanger filter (Fig. 6) in the form of at least a three-blade propeller.

Claims (1)

 A vortex evaporation-drying chamber with an inert nozzle, containing an evaporation and drying chambers with gas supply and exhaust pipelines located in a common housing, as well as a filter-heat exchanger made in the form of a nozzle from a fluidized bed of inert bodies above which the sprinkler is located, the sprinkler is made in the form of a rotating in collector bearings with a control throttle for supplying the initial solution, and the exhaust dusty gases are subjected to preliminary acoustic treatment in an acoustic installation, after which the gas stream is directed to a cyclone with a hopper, where the main part of the dry material carried away by gases is released, and the final cleaning of the gases takes place in a bag filter with a hopper, the nozzles being made in the form of acoustic nozzles, the resonator is made in the form of at least one spherical cavity located in the end wall of the housing facing the distribution head, and the spherical cavity is connected by a calibrated hole with a gap between the vertical hole in the end wall of the housing and the distribution rod the dividing head, and in a section perpendicular to the axis of the rod, the gap has an annular section, and the distribution head is made in the form of a housing with a cover in the form of truncated cones connected by large bases, and a collector in the form of a cylindrical cavity connected by an annular channel formed by an external the cylindrical surface of the hollow rod and holes of the same diameter coaxial with it, made respectively in the cover and body of the distribution head, with at least three, channels for outlet of the solution uniformly arranged around the circumference and perpendicular to the axis of the rod, and a hole cut is located on the conical surface of the distribution head cover, the angle of inclination of which determines the root angle of the spray nozzle, or the nozzle resonator is made in the form of a toroidal cavity, the axis of which is aligned with the distribution head and the cavity is connected by at least one calibrated hole with an annular gap between the vertical hole in the end wall of the core pus and the rod of the distribution head, wherein the channel for the outlet of the solution is a radial annular gap lying in a plane perpendicular to the axis of the rod of the distribution head, and formed in its cover by means of a plate rigidly attached to the rod, perpendicular to its axis, and connected with the cover, at least three fasteners with the formation of a radial annular gap, characterized in that the inert nozzle located in the heat exchanger filter is made in the form of a cylindrical ring a, on the lateral, inner and outer surfaces of which screw cutting is performed in opposite directions, or in the form of a ball on the surface of which through holes are made hemispherical in shape, or in the form of a ring on the outer surface of which a helical surface is made like a plate auger, or at least three-bladed propeller.

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