RU2669221C1 - Vortex evaporative drying chamber with inert crown - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: invention relates to the technique of solutions, melts and suspensions drying and the preparation of granules of various substances and can be used in microbiological, food, chemical and other industries. Vortex evaporative-drying chamber with inert packing contains evaporating and drying chambers located in a common housing, gas supply and discharge pipelines, as well as a filter-heat exchanger, made in the form of a nozzle from the fluidized bed of inert bodies, above which there is a sprinkler with injectors. Each of the nozzles comprises a cylindrical body with a fitting rigidly connected to a housing coaxially disposed at the upper part of the housing and having a cylindrical fluid inlet connected to a diffuser that is axisymmetric to the housing and the fitting, and in the lower part of the cylindrical hole a hollow conical swirler is fixed, the conical shell of which is fixed by means of at least three spokes fixed at one end to the conical shell of the swirler in its upper part, and at other end – in the annular groove made on the inner surface of the cylindrical hole, on the outer surface of the hollow conical swirler a screw through thread is made, and to the body, in its lower part, a sprayer is connected by means of at least three spokes located perpendicular to the axis of the body and made in the form of a solid disk, disk of the atomizer is formed by two surfaces, one of which, facing the diffuser, a curved surface, the line forming this surface is a curve of the n-th order line, and the second is the plane or the disk of the atomizer is formed by two congruent and equidistant n-order surfaces, and the spokes by which the disk of the sprayer is attached to the body are straight or curved.EFFECT: use of the nozzle of the described construction allows to obtain a uniform flow of fine droplet droplets in the range of droplet diameters from 30 to 150 mcm at a water supply pressure of not more than 1 MPa.1 cl, 2 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 Russian Federation No. 2334180, containing an evaporation 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 from a fluidized bed of inert bodies, above which an irrigator 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 objective of the invention is to increase the productivity of drying.

EFFECT: obtaining a stream of droplets of finely dispersed spray uniform in volume in the range of droplet diameters from 30 to 150 microns at a water supply pressure of not more than 1 MPa.

This is achieved by the fact that in a vortex evaporation-drying chamber with an inert nozzle, containing an evaporation 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 from a fluidized bed of inert bodies, over which an irrigator is located with nozzles, 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 aka installation, after which the gas stream is sent to the cyclone with the hopper, where the bulk 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 inert nozzle is made in the form of hollow balls with a helical groove cut on their spherical surface, or the nozzle is made in the form of a helical line formed on a spherical surface and having in cross section perpendicular to the helical line a profile such as a circle, polygon, “Berl saddle” or “Itallox” saddle, and and the nozzle is made in the form of cylindrical rings, on the side surface of which a helical groove is cut, or the nozzle is made in the form of a helix formed on a cylindrical surface and having in profile a cross section perpendicular to the helix, a profile such as a circle, polygon, Berl’s saddle or saddle Itallox, or the nozzle is made in the form of toroidal rings, or the nozzle is made in the form of toroidal rings having a profile such as a circle, polygon, Berl saddle or Itallox saddle, or the nozzle is made of elastic polymer s materials, composite materials, and obtained by molding or sintering methods. Each nozzle contains a cylindrical casing with a fitting rigidly connected to the casing and coaxially located in the upper part of the casing and having a cylindrical hole for supplying fluid connected to a diffuser, an axisymmetric casing and a fitting, and a hollow conical swirl conical in the lower part of the cylindrical hole the shell of which is fixed by means of at least three spokes fixed at one end on the conical shell of the swirler, in its upper part, and the other end in the annular groove made on the inner surface of the cylindrical hole, while on the outer surface of the hollow conical swirler a through screw thread is made, and to the body, in its lower part, by means of at least three spokes, a spray gun located perpendicular to the axis of the housing is connected and made in the form a solid disk, while the spray disk is formed by two surfaces, one of which, facing the diffuser, is a curved surface, and the line forming this surface is ivaya line n-th order, and the second - a plane or disk atomizer is formed by two congruent and equidistant surfaces n-th order, and the spokes, whereby the atomizer disc is attached to the body shape are straight or curved.

In FIG. 1 shows a vortex evaporation-drying chamber with an inert nozzle; FIG. 2 is a general view of the nozzle of the sprinkler 5, in FIG. 3 - FIG. 5 - embodiments of an inert nozzle.

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 placed 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 with nozzles is located, which is a collector rotating in bearings 12 with a control choke 13 for supplying the source 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 the lower and upper restrictive grids 6. The cylindrical drying chamber 2 is equipped with gas supplying tangential pipelines 7, 17 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 nozzles 10 and 20 (Fig. 2). For unloading the dried material, an unloading device 19 is provided, located in the hopper 18 of 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 flow is directed to a cyclone 15 with a hopper, where the bulk of the dry material carried away by the gases is released, and the final cleaning of the gases takes place in a bag filter 16.

The sprinkler nozzle 5 comprises a cylindrical housing 21 with a fitting 22 rigidly connected to the housing and coaxially located in the upper part of the housing and having a cylindrical opening 23 for supplying fluid connected to the diffuser 24, an axisymmetric housing and a fitting. A hollow conical swirl 27 is fixed in the lower part of the cylindrical hole 23 for supplying liquid, the conical shell of which is fixed by means of at least three spokes 28 fixed at one end on the conical shell of the swirl in its upper part and the other end in the annular groove of the cylindrical holes 23 (not shown), made on its inner surface. On the outer surface of the hollow conical swirl 27, a through screw thread 29 is made.

To the housing 21, in its lower part, by means of at least three spokes 26 is connected a spray gun 25 located perpendicular to the axis of the housing and made in the form of a solid disk. The atomizer disk 25 is formed by two surfaces, one of which, facing the diffuser 24, is a curved surface, and the curve of the nth order, for example, elliptical, parabolic, etc., and the second as a plane, is the line forming this surface.

The spokes 26, by means of which the atomizer disk is attached to the body, are arranged radially with respect to the axis of the body, and can be made straight and curved in shape (not shown in the drawing), moreover, they are attached to the body by means of screws, and to the disk by detachable connections, such as threaded, or one-piece, such as resistance welding.

The atomizer disk can be formed by two congruent and equidistant surfaces of the n-th order, while the nozzle atomizer is made of solid materials, such as tungsten carbide.

The nozzle with a spray disk works as follows.

Liquid under pressure is supplied into the cavity of the cylindrical hole 23 for supplying fluid to the nozzle body 21, and then into the lower part of the hole 23, and through the conical swirl 27, comes out into the atomizer 25, and additional droplets of liquid are crushed due to turbulence of the outlet stream , and the finely dispersed stream exits the nozzle with a wide torch of the atomized liquid (solution).

Using the nozzle of the described design allows to obtain a uniform flow volume of fine spray droplets in the range of droplet diameters from 30 to 150 microns with a water supply pressure of not more than 1 MPa.

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

The source material to be dried through the nozzles of 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.

Claims (1)

A vortex evaporation-drying chamber with an inert nozzle, containing the evaporating and drying chambers and gas supply and exhaust pipelines located in the common housing, as well as a filter-heat exchanger made in the form of a nozzle from a fluidized bed of inert bodies, over which an irrigator with nozzles is located, made in the form 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 an acoustic installation, after which o the gas stream is directed to a cyclone with a hopper, where the bulk of the dry material carried away by gases is released, and the final purification of gases occurs in a bag filter with a hopper, the inert nozzle is made in the form of hollow balls, on the spherical surface of which a helical groove is cut, or the nozzle is made in the form a helical line formed on a spherical surface and having a cross section perpendicular to the helical line, a profile such as a circle, polygon, Berl saddle or Itallox saddle, or the nozzle is made in the form of cyl single rings, on the side surface of which a helical groove is cut, or the nozzle is made in the form of a helix formed on a cylindrical surface and having a cross section perpendicular to the helix, a profile such as a circle, polygon, Berl saddle or Itallox saddle, or nozzle made in the form of toroidal rings, or the nozzle is made in the form of toroidal rings having a profile such as a circle, polygon, Berl saddle or Itallox saddle, or the nozzle is made of elastic polymer materials, composite material, and obtained by molding or sintering, characterized in that each of the nozzles contains a cylindrical body with a fitting rigidly connected to the body and coaxially located in the upper part of the body and having a cylindrical hole for supplying fluid connected to a diffuser, an axisymmetric body and a fitting, and in the lower part of the cylindrical hole, a hollow conical swirl is fixed, the conical shell of which is fixed by means of at least three spokes fixed at one end to the conical a swirler casing, in its upper part, and the other end - in an annular groove made on the inner surface of the cylindrical hole, while a through screw thread is made on the outer surface of the hollow conical swirler, and to the body, in its lower part, by at least three the spokes are connected to a spray located perpendicular to the axis of the housing and made in the form of a solid disk, while the spray disk is formed by two surfaces, one of which is curved in the direction of the diffuser surface, and the line forming this surface is an nth-order curved line, and the second is a plane, or the spray disk is formed by two congruent and equidistant n-order surfaces, and the spokes by which the spray disk is attached to the body are shaped straight or curved.

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