RU2645889C1 - Catalysts drying and calcination plant - Google Patents

Abstract

FIELD: machine building; technological processes.

SUBSTANCE: invention relates to solutions drying method to produce a granular product having increased hygroscopicity. In a catalyst drying and calcining unit comprising a plunger pump for supplying the mother solution, an impurity separation filter, a spray dryer for drying and granulating the catalyst from the solution, battery cyclones to catch the finished product and send it to the screw or belt conveyor of the dried product, the return draft flow is sent to the Venturi scrubber to collect it into the tank from the bunker part of the scrubber as a slurry and from the drop catcher, and the pump supplies the solution to the scrubber, wherein the fan feeds the drying agent to the calcination unit through the heat generator, and the separator supplies the dried product to the pneumatic transport cyclone, wherein the calcination unit is designed to create a two-stage temperature mode of calcination and to provide a regulated catalyst holding time in each stage: first stage is provided by feeding the drying agent to the upper part of the device, the vapor-gas medium contacting the catalyst particles is supplied to the lower part of the device, and the finished product enters the product cooler, wherein the scrubber with the drop catcher is intended for the final dust collection process of the return draft and cleaning of the drying agent discharged into the atmosphere, wherein the unit is equipped with a waste heat carrier purification system, a finished product cooling unit, a unit of dosed feed, transport of the product inside the installation, finished products bunker and other units that create the necessary infrastructure for a complete installation, wherein the wet initial product supplying system is made in the form of acoustic nozzles, each of which contains a housing with an internal acoustic oscillation generator in the form of a nozzle and a resonator, nozzles for supplying air and liquid, acoustic oscillation generator is made in form of conical nozzle coaxial with housing and having annular throttle opening with external diameter dc formed by nozzle cut and resonator rod with diameter dst and an annular volumetric resonator of length h, formed by a resonator rod and a cylindrical cavity with an outer diameter dp in the fastener, wherein the space of the cavity resonator is spaced apart from the nozzle section at a distance b, and the air supply pipe is perpendicular to the axis of the housing and is connected to an annular cavity formed by the roller and the housing inner surface, while on the roller a cage with throttling holes is fixed coaxial with the annular throttle opening, as well as coaxially fixed resonator rod, and sprayed liquid is supplied through branch pipe perpendicular to housing axis into annular hollow formed by casing and outer nozzle surface, wherein one end of the casing is made solid and is connected to the casing, and at the other end, enclosing the conical nozzle, orifice holes are made coaxial with the ring orifice hole, wherein on the side opposite to the cavity resonator an adjusting device is provided in the form of a handwheel with a gland, which is mounted on the free end of the roller, an external diffuser is coaxially attached to the nozzle casing, and an internal perforated diffuser is coaxially attached to the annular cavity resonator fastening element with the resonator rod so, that output sections of external and internal diffusers lie in one plane perpendicular to annular volume resonator axis.

EFFECT: increasing the efficiency of drying and calcination processes.

1 cl, 2 dwg

Description

The invention relates to a method for drying solutions to obtain a granular product having increased hygroscopicity.

Closest to the claimed object is a method for producing granular calcium chloride anhydrous by feeding a powdery fraction of the product (fine fraction + powder after crushing), partially dehydrated product and solution into the drum (RF patent No. 2326310, F26B 3/12, prototype).

The disadvantages of this method include, first of all, the difficulty of controlling the process in the presence of three product streams with different humidity: anhydrous powder, partially dehydrated lumpy product and solution.

The disadvantages of the device for granulating CaCl ₂ are significant costs, difficulties in controlling the process due to the large number of input streams and low reliability of the process due to significant deposits in the drum.

The technical result is an increase in the efficiency of drying and calcining processes.

This is achieved by the fact that in the installation for drying and calcining the catalyst, containing a plunger pump for supplying the initial solution, an impurity separation filter, a spray dryer designed for drying and granulating the catalyst from the solution, battery cyclones for capturing the finished product and sending it to the screw or belt the conveyor of the dried product, the exhaust stream is sent to the Venturi scrubber with a smoke exhauster to collect it into the tank from the bunker part of the scrubber as sludge and from the droplet eliminator, and the pump carries out I supply the solution to the scrubber, while the fan feeds the drying agent through the heat generator into the calcining apparatus, and the separator delivers the dried product to the pneumatic conveying cyclone, and the calcining apparatus is designed to create a two-stage temperature calcination regime and ensure a regulated catalyst residence time in each stage: the first stage provided by the supply of a drying agent to the upper part of the apparatus, the vapor-gas medium in contact with the catalyst particles is supplied They are sent to the lower part of the apparatus, and the finished product enters the product cooler, while the scrubber with a droplet eliminator is intended for the final process of dust retention and cleaning of the drying agent leaving the atmosphere, while the installation is equipped with a waste heat carrier cleaning system, a finished product cooling unit, a dosed supply unit , transporting the product inside the installation, the finished product hopper and other nodes that create the necessary infrastructure for the complete installation, while the system giving the wet initial product is made in the form of acoustic nozzles, each of which contains a housing with an acoustic oscillator located inside the nozzle and resonator, nozzles for supplying air and liquid, the acoustic oscillator is made in the form of a conical nozzle, coaxial with the housing and having an annular throttle a hole with an external diameter dc formed by a nozzle exit and a resonator rod with a diameter dst and an annular volume resonator of length h formed by a resonator rod and a cylinder a cavity with an outer diameter dp in the fastener, while the cavity of the cavity resonator is spaced b from the nozzle exit and the nozzle for supplying air is perpendicular to the axis of the housing and connected to an annular cavity formed by a roller and the inner surface of the housing, while a cartridge with throttle holes coaxial with the annular throttle hole, and the resonator rod is coaxially fixed, and the sprayed liquid is supplied through a pipe located perpendicular to the axis of housing in the annular cavity formed by the casing and the outer surface of the nozzle, while one end of the casing is solid and connected to the body, and in the other end, covering the conical nozzle, throttle holes are made, coaxial with the annular throttle hole, while on the side opposite to the volumetric To the resonator, an adjustment device is provided in the form of a handwheel with an oil seal, which is mounted on the free end of the roller, an external diffuser is coaxially attached to the nozzle casing, and an annular volume is attached to the fastener th resonator with a resonator rod coaxially fixed inner perforated diffuser so that the output cross section of the outer and inner cones lie in one plane perpendicular to the axis of the annular cavity.

In FIG. 1 is a diagram of a proposed apparatus for drying and calcining a microspherical cracking catalyst; FIG. 2 is a diagram of a pneumatic acoustic nozzle.

The apparatus for drying and calcining a microspherical cracking catalyst comprises a plunger pump 1 for supplying an initial solution, an impurity separation filter 2; spray dryer 3 with nozzles located in the upper part of the dryer, designed for drying and granulating the catalyst from the solution, battery cyclones 4 for collecting the finished product and sending it to the screw or belt conveyor of the dried product. By a smoke exhauster 5, a stream of reture (non-marketable trifles) is sent to a Venturi scrubber 6 to collect it into a tank 10 from the hopper part of the scrubber as sludge and from a droplet eliminator 7. Pump 8 delivers the solution to the scrubber 6, and the drying agent is fed through the heat generator to the calcining agent apparatus 12. The separator 11 delivers the dried product into the cyclone 13 pneumatic transport. The heat generator is designed to produce a drying agent and has a fitting for supplying air and fuel and draining the drying agent into the dryer 3.

The acoustic nozzle (figure 2) contains a cylindrical body 16 with an ultrasonic frequency range acoustic oscillator located inside it, made in the form of a conical nozzle 25, coaxial with the housing 16 and having an annular throttle aperture 26 with an outer diameter dc formed by a nozzle exit and a resonator rod 27 diameter dct and an annular volume resonator 29 of length h formed by the resonator rod 27 and a cylindrical cavity with an outer diameter dp in the fastener 28, while the cavity is resonant 29 and is spaced from the nozzle section 25 in the region b. Air is supplied under pressure through a pipe 18 located perpendicular to the axis of the housing 16 into an annular cavity 22 formed by a roller 19 and an inner surface of the housing 16. A cage 20 is fixed to the roller 19 with throttle holes 21 coaxial with the annular throttle hole 26, and also resonantly coaxially fixed rod 27. The sleeve 20 contacts in a sliding fit with the cylindrical shank of the nozzle 25. The sprayed liquid is supplied through a pipe 17 located perpendicular to the axis of the housing 16 into the annular cavity 30 formed th casing 23 and the outer surface of the nozzle 25, while one end of the casing is solid and connected with the housing 16, and in the other end, covering the conical nozzle 25, are made throttle holes 24, coaxial with the annular throttle hole 26.

To change the degree of dispersion of the solution in the housing 16 from the side opposite to the volume resonator 29, an adjustment device is provided in the form of a handwheel 31 with an oil seal, which is mounted on the free end of the roller 19.

For optimal operation of the nozzle, the following ratios of its parameters must be observed:

the ratio of the length h of the annular volume resonator 29 to the distance b from the open surface of the cavity of the volume resonator 29 to the nozzle exit 25 lies in the optimal range of values: h / b = 0.7 ÷ 1.3;

the ratio of the outer diameter dp of the annular volume resonator 29 to the diameter dct of the outer cylindrical surface of the resonator rod 27 lies in the optimal range of values: d _p / d _article = 1.2 ÷ 1.9;

the ratio of the diameter dc of the annular throttle hole 26 of the nozzle to the diameter dct of the outer cylindrical surface of the resonator rod 27 lies in the optimal range of values: d _c / d _article = 1.1 ÷ 1.7.

An external diffuser 32 is coaxially attached to the nozzle casing 23, and an internal perforated diffuser 33 is coaxially attached to the fastener 28 of the annular volume resonator 29 with the resonator rod 27 so that the output sections of the external and internal diffusers lie in one plane perpendicular to the axis of the ring volume resonator 29 .

The acoustic nozzle operates as follows.

The spraying agent, for example air, is supplied through the nozzle 18 to the cavity 22, then through the throttle holes 21 of the cage 20 into the annular throttle hole 26 with an outer diameter dc formed by the nozzle exit and the resonator rod 27, and then encounters an annular volume resonator 29 in its path. As a result of the passage of the resonator 29 by a spraying agent (for example, air), pressure pulsations arise in the latter, creating acoustic vibrations, the frequency of which depends on the parameters of the resonator. The acoustic vibrations of the spraying agent contribute to finer atomization of the fluid supplied through the pipe 17 to the cavity 30 formed by the casing 23 and the outer surface of the nozzle 25, from where it enters the throttle holes 24 in the end face of the casing 23 and then breaks up into small droplets under the influence of acoustic air vibrations, as a result, a torch of the sprayed solution with air forms, the root angle of which is determined by the angle of inclination of the conical surface of the nozzle 25. Experiments have shown that at an air pressure of 100 kPa, the average diameter of the droplets is 90 microns, with an increase in air pressure by about 4 times (up to 400 kPa), the average diameter of the droplets decreases slightly and amounts to 87 microns.

The calcination apparatus 12 is designed to create a two-stage temperature regime of calcination and to provide a regulated residence time of the catalyst in each stage: the first stage is provided by the supply of a drying agent to the upper part of the apparatus, the vapor-gas medium in contact with the catalyst particles is supplied to the lower part of the apparatus, and the finished product enters the product cooler 14. A Venturi scrubber 15 with a droplet eliminator is designed for the final process of dust retention and cleaning of the effluent Yeru drying agent. The installation is equipped with a waste heat carrier cleaning system, a finished product cooling unit, a dosed supply unit, a product transport inside the unit, a finished product hopper, and other units that create the necessary infrastructure for the complete installation.

Installation for drying and calcining the catalyst operates as follows.

The quality of the catalyst is finally formed in the calcining apparatus 12. Using the favorable physicomechanical properties of the product microspheres, in particular their high flowability, when developing the column apparatus 12 with conductive heat transfer to the catalyst, three necessary conditions for the quality of the process were realized, which could not be done before under the conditions columns with convective calcination mode:

- two-stage temperature mode;

- regulated catalyst residence time in each stage;

- vapor-gas medium in contact with the catalyst particles.

Technical characteristics of the proposed installation: performance of the finished product - 500 kg / h; gas consumption - 1280 m ³ / h; installed power - 700 kW.

The installation is characterized by an energy-efficient process due to the heat use of the spent heat carrier of the calcining furnace as a drying agent.

One of the most effective catalysts in oil refining is the aluminosilicate microspherical catalyst. In the proposed installation, a new design of the spray drying chamber was developed: changing the gas distribution system with a local coolant supply to each nozzle, as well as replacing the dispersion method, created conditions for obtaining an enlarged and more uniform grain composition with uniform heat treatment of dispersed particles in the dryer.

A variant is possible when an additional flow divider is made coaxially to the external diffuser 32, made in the form of a cylindrical shell 34, on the end part of which from the side opposite to the diffuser 32, a perforated plate 35 is fixed.

Claims (1)

Installation for drying and calcining the catalyst, containing a plunger pump for supplying the initial solution, an impurity separation filter, a spray dryer designed for drying and granulating the catalyst from the solution, battery cyclones for collecting the finished product and sending it to the dried product auger or conveyor belt, smoke exhaust the reture is sent to a Venturi scrubber to collect it into the tank from the hopper part of the scrubber as sludge and from a drop eliminator, and the pump delivers the solution to the scrub er, in this case, the drying agent is fed through the heat generator to the calcining apparatus, and the separator delivers the dried product to the pneumatic conveying cyclone, and the calcining apparatus is designed to create a two-stage calcination temperature regime and ensure a regulated catalyst residence time in each stage: the first stage is provided by the supply of the drying agent in the upper part of the apparatus, the vapor-gas medium in contact with the catalyst particles is fed into the lower part of the apparatus a, and the finished product enters the product cooler, while the scrubber with a droplet eliminator is intended for the final process of retur dust collection and cleaning of the drying agent entering the atmosphere, while the installation is equipped with a waste heat carrier cleaning system, a finished product cooling unit, a dosed food unit, and product transport inside installation, the finished product hopper and other nodes that create the necessary infrastructure for the complete installation, characterized in that the wet supply system the initial product is made in the form of acoustic nozzles, each of which contains a housing with an acoustic oscillator located inside the nozzle and resonator, nozzles for supplying air and liquid, the acoustic oscillator is made in the form of a conical nozzle, coaxial with the housing and having an annular orifice with outer diameter dc formed by a nozzle exit and a resonator rod with a diameter dst and an annular volume resonator of length h formed by a resonator rod and a cylindrical with an external diameter dp in the fastener, while the cavity of the cavity resonator is separated from the nozzle exit at a distance b, and the pipe for air supply is perpendicular to the axis of the casing and connected to the annular cavity formed by the roller and the inner surface of the casing, while the cage is fixed to the roller with throttle holes coaxial with the annular throttle hole, and the resonator rod is coaxially fixed, and the sprayed liquid is supplied through a pipe located perpendicular to the axis of the housing in the ring th cavity formed by the casing and the outer surface of the nozzle, while one end of the casing is solid and connected to the body, and in the other end covering the conical nozzle, throttle openings are made, coaxial with the annular throttle hole, while on the side opposite to the volume resonator, An adjustment device is provided in the form of a handwheel with an oil seal, which is mounted on the free end of the roller, and the ratio of the length h of the ring cavity to the distance b from the open surface of the cavity the resonator to the nozzle exit lies in the optimal range of values: h / b = 0.7 ÷ 1.3; the ratio of the outer diameter dp of the annular volume resonator to the diameter dst of the outer cylindrical surface of the resonator rod lies in the optimal range of values: d _p / d _article = 1.2 ÷ 1.9; the ratio of the diameter dc of the annular throttle aperture of the nozzle to the diameter dst of the outer cylindrical surface of the resonator rod lies in the optimal range of values: d _c / d _article = 1.1 ÷ 1.7, an external diffuser is coaxially attached to the nozzle casing, and to the fastener of the ring volume resonator an internal perforated diffuser is coaxially attached to the resonator rod so that the output sections of the external and internal diffusers lie in the same plane perpendicular to the axis of the annular volume resonator to the external fuzoru acoustic nozzle coaxially attached additional flow divider configured as a cylindrical shell, on which the end portion on the side opposite the diffuser, fixed perforated plate.

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