RU2332347C1 - Unit for transporting granular material in fluidised state (versions) - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention pertains to non-ferrous metallurgy and specifically to transportation of granular material in fluidised state according to requirements and can be used in electrolytic production of aluminium for transportation of alumina from the collecting bin to feed bins. The unit consists of a collector bin (1), equipped with an off-loading cone (2), joined by an air slide conveyor (3) to not less than one single type loading module (6), consisting of transport and feed air slide conveyors (8). The unit is equipped with a unified system of supplying aerating gas, including a unified pneumatic track with gas outlet connection pipes, with a valve system. In the first alternative there is unit with a unified pneumatic gas outlet connection pipe joined to the first in the direction of putting alumina in the section of the feed air slide conveyor. In the second alternative, the unit is made such that, each section of the feed air slide conveyor is joined to the unified pneumatic gas outlet connection pipe. The invention provides for high cost effectiveness, high degree of reliability, working efficiency and reparability, as well as flexible operational control of the process of transporting granular material with minimum energy losses and low consumption of the aerating gas.

EFFECT: flexible operational control of the process of transporting granular material with minimum energy losses and low consumption of the aerating gas, increased cost effectiveness, reliability and reparability of the process.

8 cl, 4 dwg

Description

The invention relates to the field of transporting bulk material in a fluidized state through pipelines and can be used in the electrolytic production of aluminum for transporting alumina from a storage hopper to a supply hopper.

It is known that to obtain 1 ton of aluminum, it is necessary to feed about two tons of alumina into the electrolyzer. From this, the relevance of developing and improving the centralized distribution of alumina is clear, the use of which gives significant advantages compared to the traditional loading of alumina directly into consumable bins installed on the electrolyzer, namely:

- reduces labor costs;

- Releases processing equipment, in particular, multi-operation cranes;

- reduces the loss of alumina;

- stabilizes the electrolysis process, etc.

Of the existing methods for transporting bulk material in a fluidized state, the method of transportation in a “hyperdense bed” is of interest.

A description of the technical essence of the method of transportation in a “hyperdense layer”, principles of designing devices for transportation in this way, as well as a description of a typical design developed on the basis of these principles are given in the patent of the French company PECHINEY ALUMINUM No. 2534891 “Closed potential fluidization device for horizontal feeding bulk materials ”(priority of 10.22.1982; B65G 53/20, C25C 3/14).

The method of transporting bulk material in a fluidized state in a "hyperdense bed", implemented by the device according to the aforementioned French patent, is by far the most efficient and industrially mastered. Moreover, the high efficiency of the method is proved by the implementation of this principle of transportation by different companies and on electrolyzers of various designs and capacities. To date, the company "PECHINEY ALUMINUM" improves and develops this method, as evidenced by a number of patents:

- FR No. 2575734 "Device for the distribution of fluidized powder material with an adjustable flow rate" (priority 01/08/1985);

- FR No. 2562878 "Closed device of potential fluidization for horizontal supply of bulk material in a dense layer" (priority 04/12/1984);

- FR No. 2575680 "Fluidization apparatus for the separation of two mixed solid phases" (priority 08/01/1985);

- FR No. 2778393 "Method of transportation in a hyperdense bed of fluidized material and a device for its implementation" (priority 05/11/1998);

- FR No. 2779136 "The device of the bypass channel for the transportation of fluidized powder material" (priority 02.06.1998);

- Patent RU No. 2076782 “Device for pneumatic transportation in a fluidized bed on a porous base of a powdery material and for determining the clogging of a porous base and a method for determining clogging of a porous base” (filing date of the Convention application 26.12.1990);

- Application for the grant of a patent of the Russian Federation No. 2004116083 “System for the distribution of powdered material with controlled mass flow rates” dated May 26, 2004 (priority of French application 02/03598 of October 21, 2002).

Currently, this method of transportation, being the most promising in technical terms and generally available due to the expiration of the main patent (FR No. 2534891), is the basis for the development of transport systems of many interested companies. Thus, significant achievements in the development and improvement of transport systems based on the method of transporting bulk material (alumina) in the “hyperdense layer” have been achieved by Chinese experts.

In the complex proposed by the applicant, the transportation of bulk materials is carried out by aerofluids in a fluidized state. In this regard, the technical solution according to the patent of the French company "PECHINEY ALUMINUM" No. 2534891 "Closed potential fluidization device for horizontal feeding of bulk materials" (priority from 10/22/1982; B65G 53/20, С25С 3/14) was chosen as the closest analogue (prototype), as the closest in technical essence, design, the presence of similar, essential features.

The technical solution for the prototype proposed "... the process of continuous supply of bulk material (for example, alumina) from a container containing bulk material into various containers and industrial plants: bags, containers, extrusion presses, electrolyzers". According to this patent, a closed potential fluidization device for supplying bulk materials from the zone of their accumulation to the zone of consumption includes between these two zones at least one horizontal or inclined conveyor equipped with fluidization means containing a lower channel for gas circulation and an upper channel for circulation of pulverized material and gas, between which installed the porous partition, the device includes at least one pipe for supplying gas to the lower channel and at least one balance a supporting column whose filling height balances the pressure of the potential fluidization gas.

The development of the prototype is of interest in theoretical terms, but from a practical point of view is not of interest, since it has a number of significant drawbacks:

- the prototype provides for a continuous process for feeding alumina to consumable bins of electrolysis cells, that is, in proportion to the production, there is a continuous loading of alumina into consumable bins. To implement this method of power supply, the device must be in the operating mode (in the state of fluidization) continuously, and this is associated with a significant unproductive consumption of aerating gas, electricity;

- taking into account the abrasiveness of bulk materials, including alumina, there is intense wear of equipment with a significant reduction in its service life and an increase in operating costs;

- current and overhaul of the device according to the prototype is possible when it is completely stopped;

- operational wear of metal structures in a continuous fluidization mode leads to an increase in the iron content in aluminum;

- continuously being in a state of fluidization, alumina changes its physicochemical and rheological properties, which negatively affects the electrolysis process as a whole;

- the presence of through aeration channels in aerated chambers of the prototype in the case of transporting bulk material over considerable distances requires an increase in the pressure of the aerating gas, an increase in the speed of transportation and, accordingly, an increase in the height of the leveling columns;

- in the conditions of supplying aerating gas to the through aeration channel, it is practically impossible to ensure absolute reproduction of the conditions for transporting material along the entire transport system.

The objective of the invention is the creation of an economical industrial complex for transporting bulk material in a fluidized state with a high degree of reliability, availability and maintainability.

The technical result of the proposed development is to provide continuous industrial technological processes with raw materials with the possibility of flexible operational management of the process of transporting bulk material with minimal energy costs and low aerating gas consumption.

The technical result can be achieved by using a complex made both according to the first independent claim (claim 1), and according to the second independent claim (claim 6).

In the first version of the proposed solution, the technical result is achieved in that the complex for conveying in a fluidized state bulk material from the storage hopper to the supply hoppers, including at least one horizontal or inclined aeration channel equipped with an aeration gas supply system and containing a lower aeration channel with at least one pipe for supplying gas, and the upper transport channel with at least one column, moreover, between the lower aeration and upper transport channels an aerogel and a gas-permeable partition is installed, made of the same loading modules, equipped with a single aeration gas supply system, including a single pneumatic system with gas outlet pipes, equipped with a damper system, each loading module includes a cascade of transport air channels and a group of consumable air channels, and transport air channels are made in the form of a set sections, each of which is connected to the pneumatic outlet by a gas outlet pipe, and consumable air chutes are made in the form of a set of sections, in which a pneumatic outlet with a gas exhaust pipe connected to the first section of the flow of aerogloo along the supply of alumina. At the same time, the sections of transport aerial channels are equipped with bypasses, each consumable aerial channel is equipped with a multi-stage electrical insulation system, the columns are equipped with filters, and the aeration gas supply system is capable of redistributing gas between the consumable aerial channels of one loading module.

In the second version of the proposed solution, the technical result is achieved in that the complex for the fluidized transportation of bulk material from the storage hopper to the supply hoppers, including at least one horizontal or inclined aeration channel equipped with an aeration gas supply system and containing a lower aeration channel with at least one pipe for supplying gas, and the upper transport channel with at least one column, and between the lower aeration and upper transport channels of the aerogel a gas permeable partition is installed, made of the same type of loading modules, equipped with a single aeration gas supply system, including a single pneumatic system with gas outlet pipes, equipped with a damper system, each loading module includes a cascade of transport air channels and a group of consumable air channels, transport and consumable air channels in the form of a set of sections, each of which is connected to the air duct by a gas outlet pipe. At the same time, the sections of transport aerial channels are equipped with bypasses, each consumable aerial channel is equipped with a multi-stage electrical insulation system, the columns are equipped with filters, and the aeration gas supply system is capable of redistributing gas between the consumable aerial channels of one loading module.

The choice of one or another variant of the implementation of the complex is determined in each case, based on the optimization of technological requirements and design features of technological equipment.

The technical essence of the proposed solution is as follows.

To date, the transportation of alumina in a fluidized state is an urgent problem. The complexity of solving this problem is determined by both the length and ramification of the transport routes, and the features of the transported material. The negative factors should also include the factor of significant gas consumption for transportation of alumina.

In the alleged invention, all of these problems are solved as follows:

- an extended branched transport line is divided into the same type of loading modules that operate autonomously from each other and ensure the supply of material to a specific group of electrolyzers;

- to ensure the reliability of the complex as a whole, all modules are powered from a single aeration gas supply system and controlled by a single control system;

- gas supply through the modules is carried out in a cyclic mode, and the loading time of one module can vary from 1 to 60 minutes, and the main time the module is idle (up to 10 hours);

- the frequency of supply of material through the modules allows with maximum efficiency to use the energy of the fluidized material directly to its delivery to the consumables of the electrolyzer; there are practically no unproductive energy losses to maintain a fluidized system in an equilibrium state. In this regard, the performance of the entire complex is provided by fans of low power;

- to stabilize the operation of the module and reproduce the conditions for the supply of material in certain sections of the transport highway of the module, gas is supplied to the aeration channel from a single pneumatic pipe;

- for the same purpose, the transport air duct consists of sections of the same type, the upper part of which together forms a through transport channel of the air duct, and the lower one forms the aeration channel, which is divided sectionally into autonomous aeration gas supply sections;

- to simplify the design of the complex as a whole, the transport and aeration channels of the expendable aeration channel are made end-to-end (according to the first embodiment of the complex), but it is possible to carry out a discharge aeration channel similar to the transport (the second embodiment of the complex);

- for additional stabilization of the alumina feed process, the aeroflows are equipped with a bypass system.

Thus, in order to increase the reliability of the complex when using small tilt angles of aerial gutters (or aerial gutters that do not have a tilt) and reduce air consumption for aeration of alumina, the proposed solution reduces the length of a simultaneously operating transport line. The number of modules in the complex is determined in each case, based on the power of the aerating gas supply system and the design features of aerial chutes: for example, the angle of inclination, the ratio of the dimensions of the transport and aeration channels, etc.

The movement of alumina through the modules is controlled by providing air supply to the desired module. The operability of the complex is ensured by the precise control of the operation of the fans and the electric gate of the pneumatic box, and in the proposed complex the control can be carried out both in automatic and “manual” mode.

Transport aerial channels of the complex can be performed both at one level and at different levels, depending on specific requirements. With a multi-level transport system, to ensure the material is transferred from level to level, the transport chutes are equipped with a special reloading device.

The closest analogue and the proposed technical solution are characterized by the following common features:

- transportation of bulk material is carried out in a fluidized state;

- the extreme points of the transport system are the storage hopper and consumables;

- the transport system consists of horizontal and / or inclined aerial channels, each of which consists of a lower aeration channel, an upper transport channel and a gas-permeable partition;

- equipped with an aeration gas supply system;

- the upper transport channel is equipped with columns.

Presented by the authors of the claims claimed the following distinctive features from the prototype signs:

- a complex for transporting bulk material is made of the same type of loading modules that operate autonomously from each other;

- the complex is equipped with a single aeration gas supply system for modules;

- a single system for supplying aerating gas includes a single air duct with gas outlet pipes;

- for the transfer of aerating gas from the module to the pneumatic module, the system is equipped with a system of controlled dampers;

- transport aeroshaft module made in the form of a set of sections;

- each section of the transport air duct is connected to the air duct by a gas outlet;

- sections of transport aerial channels equipped with bypasses. Bypass installation is provided for troubleshooting without stopping the process.

This node improves the operating and repair conditions of the complex, therefore it is submitted to the dependent claim;

- consumable aeroguns of the module according to the first embodiment of the complex are connected to the pneumatic duct by one exhaust pipe, and according to the second embodiment, each section of the consumable aeroshaft has its own gas supply;

- columns are equipped with filters. This distinguishing feature needs to be emphasized: in the claimed solution, the columns are equipped with filters due to the fact that the function of the columns in the proposed complex has changed somewhat compared to the prototype.

In the prototype, the columns, called balancing, are the most critical unit, ensuring the operability of the power system as a whole. In the conditions of continuous operation of the material supply system, it is necessary to maintain the system in equilibrium and the balancing columns perform the function of locking elements, and therefore the top layer of the material of the columns practically does not change its physical state. Hence there is no need for filters.

In the claimed solution, the supply of the material modulo is carried out in a cyclic mode, and sequentially from the air duct to the air duct. Aerial chutes are equipped with dampers, which allows simulating the transportation of material in a fluidized state and without completely locking the loaded aerial chute with balancing columns, that is, without imparting a “hyperdense fluidized state” to the bulk material. The equilibrium state of the material, similar to the prototype, is practically not observed, since the material is rapidly sent to the consumable hoppers of the module and its supply stops after filling the consumables. During the entire period of loading the module, the bulk material is moving in the direction of the feed hoppers, filters are installed to clean the possible emissions of excess aerating gases.

This feature is not entered into an independent claim, since the presence of filters on the columns, in general, does not affect the performance of the system, but improves the environmental conditions in production facilities.

The presence in the proposed technical solution of the above signs that are different from the signs of the closest analogue allows us to conclude that it meets the condition of patentability “novelty”.

In order to determine the “prior art”, a search was conducted on patent and scientific and technical literature. The analysis showed that fundamentally separate features of the object of protection are known:

- EA patent No. 004640 “Method and system for the distribution of fluidized materials” (IPC B65G 53/20, priority of NORSK HUDRO ASA (NO) from 2001.03.21) with periodic transportation and distribution to bulk receivers of bulk material through pneumatic conveyors is known . But this system works with high speeds of the material, because the conveyors are not filled to the top with fluidized material;

- the presence of filters in the systems for transporting fluidized bulk materials is known from French patent No. 2562878 "Closed potential fluidization device for the horizontal supply of bulk materials in a dense layer" (f. "PECHINEY"). According to the patent, the dust-containing gas collection system is located above the level of the transported bulk material;

- the presence of dampers in fluidization systems is known from French patent No. 2575680 "Fluidization apparatus for separating two mixed solid phases" (f. "PECHINEY"), in which the dampers are installed to periodically lock the transport channel;

- the presence of bypass channels in systems with fluidized material is known from French patent No. 2779136 "The device of the bypass channel for transporting fluidized powder material" (f. "PECHINEY"). The bypass channel is made as a whole in the system and is designed to bypass obstacles;

- the presence of a system for monitoring and controlling the process of transporting powdered material is known from French patent No. 2778393, “Method of transportation in a hyperdense bed of fluidized material and a device for its implementation,” which provides for monitoring pressure in the air channel located above the transported material.

During the search and comparative analysis, no solutions were identified that are characterized by identical or equivalent features to the proposed solution, namely:

- not found aerial chute, made in the form of a set of sections, each of which has an individual sidebar into a single pneumatic duct;

- not found aeroglot, in which the aeration channel is sectionally broken by gas-tight walls, with each section provided with a bypass;

- a complex (system) was not found for transporting bulk material by aerogloves that differ in different designs within the same module (the first embodiment of the complex in the claims);

- not found a complex (system) for transporting bulk material by aerial channels made of the same type of loading modules that work autonomously from each other in a cyclic mode.

Given the foregoing and taking into account the fact that the use of a combination of known and unknown features characterizing the proposed technical solution in the amount presented in the claims allows us to reach a new level in the development of promising systems for transporting bulk material in a fluidized state, we can conclude that the proposed solutions to the patentability condition “inventive step”.

An example of a specific implementation of the complex is given in relation to the transportation of alumina (TsRG), but this does not exclude the possibility of using any bulk material with the ability to saturate gas as a transported material.

An example of a specific implementation of the complex for transportation in a fluidized state of bulk material.

The proposed complex for transporting bulk material is shown in figure 1, 2, 3, 4: figure 1 - transport and hardware scheme of the complex; figure 2 is a schematic diagram of the control of a single system for supplying aerated gas; figure 3 (type A) - aeroglove with sectional gas supply; figure 4 (view B) - aerogloob with gas supply through a single pipe.

This complex is designed for an electrolysis cell equipped with powerful electrolyzers (the need for alumina per electrolysis cell is more than 4 tons per day). The complex is equipped with a single aerating gas supply system with three working fans (fan electric motor power is 11 kW) and uninterruptedly provides 104 electrolysis cells with alumina.

The complex (see Fig. 1) has two storage bins 1 installed in the inter-housing space and provided in the lower part with two discharge cones 2, each of which is connected to the corresponding feeding transport aerial channel 3, equipped with columns 4, equipped with filters 5 (see figure 3), in which alumina is transported into the body of the cell. Each feeding transport aeroglove 3 supplies alumina with two of the same type of loading module 6, each of which consists of a main transport aeroglove 7 and a group of the same type of consumable aerogloves 8, equipped with columns 9, equipped with filters 10 (see Fig. 4). Consumable air chutes 8 are also equipped with consumable bins 11, and in the last consumable hopper of each consumable air chute, an alumina level sensor 12 is installed. The number of consumables is determined by the number of entry points of alumina into the cell. In an exemplary complex, each cell is equipped with six feed hoppers. The work of the complex is ensured by a unified aeration gas supply system, including a unified pneumatic air duct 13 with gas outlet pipes 14 (see Fig. 3), four fans 15, 16, 17, 18, one of which is a backup (18), an electric shutter system 19 ... 34 (in the given example, 16 electric shutters) installed in the pneumatic box 13 (see figure 2). The proposed complex provides the ability to work both in the "automatic" and in the "manual" mode of operation of the electric shutter.

In the proposed complex, the aeration channels of transport and consumptive air chutes can be made both of the same type and with a significant difference, namely:

- in the first independent claim, a complex is claimed in which the transport aeroflows are made in the form of a set of sections 35 consisting of a lower aeration channel 36, an upper transport channel 37 and a gas-permeable partition 38 between them. Each section 35 is connected to the air duct 13 by the exhaust pipe 14 and is equipped with a bypass 39 (see figure 3). Consumable aeroshaft made in the form of a set of sections 40 (see figure 4). Only 13, the first section 42 of the expendable aeroglobe is connected to the pneumatic duct 13 by the exhaust pipe 41;

- in the second independent claim, a complex is claimed in which the transport and consumable aeroshaft are made of the same type (from the point of view of gas supply), in the form of a set of sections 35 (see figure 3).

Transport and consumable aerogloves of the complex can be performed both at one level and at different levels, depending on specific requirements. To ensure material overload from level to level down the cascade, transport aerosheets are equipped with a device for supplying bulk material from one transport aeroshaft to the next downstream cascade 43 (see figure 3).

To improve operational safety, the complex is equipped with a multi-stage electrical insulation system for consumable aerofunds (see figure 4). This system includes a gas outlet 41 of section 42 and an alumina feeding pipe 44 made of an insulating material, such as rubber cord. Also consumable aeroglove 8 is equipped with an electrical insulating unit 45.

The proposed complex for transportation in a fluidized state of bulk material-alumina (TSG) works as follows.

The launch of the complex is carried out sequentially (modularly): first, the feeding transport aerial chutes 3 are filled with alumina, then the main transport aerial chutes 7 and then consumable aero chutes 8.

To control the start-up and operation of the complex, a control concept has been developed for controlling a single aerating gas supply system that works equally efficiently in both “automatic” and “manual” modes.

The launch of the complex is as follows:

- the electric damper 22 opens, after its full opening the working fans 15, 16, 17 are started and their shutters 19, 20, 21 are opened;

- the shutter 23 opens, after its complete opening, the countdown of the set working time for module 6 ₁ starts (the lower index indicates the serial number of the module);

- at the end of the working time of loading, the shutter 23 closes;

- after completely closing the shutter 23, the shutter 24 opens and the countdown of the set time for module 6 ₂ begins;

- at the end of the working time of loading, the shutter 24 closes;

- after the shutter 24 is completely closed, the shutter 27 opens and the shutter 22 closes at the same time;

- after fully opening the shutter 27 and closing the shutter 22, the shutter 25 opens and the countdown of the set working load time for module 6 ₃ begins;

- at the end of the working time of loading the shutter 25 closes;

- after the shutter 25 is completely closed, the shutter 26 opens and the countdown of the set loading time for module 6 ₄ begins;

- at the end of the working time of loading, the shutter 26 closes;

- after the shutter 26 is completely closed, the shutter 28 opens and the shutter 27 closes at the same time;

- after fully opening the shutter 28 and closing the shutter 27, the shutter 29 opens and the countdown of the set working time for module 6 ₅ begins;

- at the end of the working time of loading the shutter 29 is closed;

- after the shutter 29 is completely closed, the shutter 30 opens and the countdown of the set load time for module 6 ₆ begins;

- at the end of the working time of loading the shutter 30 is closed;

- after the shutter 30 is completely closed, the shutter 33 opens and the shutter 28 closes at the same time;

- after fully opening the shutter 33 and closing the shutter 28, the shutter 31 opens and the countdown of the set working time for module 6 ₇ begins;

- at the end of the working time of loading the shutter 31 is closed;

- after completely closing the shutter 31, the shutter 32 opens and the countdown of the set working time for module 6 ₈ begins;

- at the end of the working time of loading the shutter 32 is closed;

- after the shutter 32 is completely closed, the fans stop, the shutter 33 closes, the shutters of the fans 19, 20, 21 are closed, the complex returns to its original state and the countdown time of the complex begins;

- at the end of the downtime, the cycle repeats again.

For the complex shown as an example, it is envisaged to change the loading time of one module from 1 minute to 60 minutes, as well as changing the downtime of the complex from 1 hour to 10 hours, followed by a repeat of the loading cycle of the modules.

If the complex is launched for the first time or after a major overhaul (the transport section of the central heating plant without alumina), then to fill the supply and main air ducts, the gas supply to the consumable air ducts is shut off.

To ensure the reliability of the complex, a sensor for the upper level of alumina is installed in the last feed hopper of each feed aerogloo

Currently, the given complex of centralized distribution of alumina (TsRG) is successfully operating at one of the Russian aluminum plants. A high degree of reliability, ease of maintenance, low energy consumption of this complex make it possible to recommend it for equipping the production capacities of newly constructed and modernized plants.

Claims (8)

1. A complex for conveying in a fluidized state bulk material from the storage hopper to the supply hoppers, including the same type of loading modules equipped with aerosheaths with columns, and an aeration gas supply system, characterized in that the aeration gas supply system is the same for all loading modules and includes a single pneumatic pipe with gas outlet pipes, equipped with a damper system, with each loading module including a cascade of transport air ducts and a group of consumables x airslides, wherein the transport chanels are formed as set of sections, each of which is connected to a single pnevmotrassoy gas exhaust pipe, and consumable chanels are formed as set of sections, wherein a single pnevmotrassoy gas exhaust pipe connected downstream the first feeding section consumable alumina chanels. 2. The complex according to claim 1, characterized in that the sections of the transport aerial channels are equipped with bypasses. 3. The complex according to claim 1, characterized in that the columns are equipped with filters. 4. The complex according to claim 1, characterized in that each consumable aero channel is equipped with a multi-stage electrical insulation system. 5. A complex for transporting bulk material from a storage hopper to a supply hopper in a fluidized state, including loading modules of the same type equipped with aerated chutes with columns, and an aeration gas supply system, characterized in that the aeration gas supply system is the same for all loading modules and includes a single pneumatic pipe with gas outlet pipes, equipped with a damper system, with each loading module comprising a cascade of transport aerial chutes and a group of consumable aero gutters, moreover, transport and consumable air channels are made in the form of a set of sections, each of which is connected to a single pneumatic duct by a gas outlet pipe. 6. The complex according to claim 5, characterized in that the sections of the transport and consumable air channels are equipped with bypasses. 7. The complex according to claim 5, characterized in that the columns are equipped with filters. 8. The complex according to claim 5, characterized in that each consumable aerial channel is equipped with a multi-stage electrical insulation system.

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