RU75654U1 - COMPLEX FOR PROCESSING BIOMASS - Google Patents

Abstract

The utility model relates to the field of equipment for processing waste having high humidity, for example, sewage sludge, sludge, manure, and obtaining raw materials from them for the production of products, products themselves, and various types of fuel.

The biomass processing complex contains a biomass dehydrator, a dryer, a gas generator with an ash pan, the gas outlet of which is connected to a gas purification and cooling device, as well as transporting means for moving the processed biomass and products derived from it. The complex is equipped with a heat generator, at least one additional dehydrator, a device for granulating or briquetting the dried biomass, dehydrators are connected in series with each other, the heat exchanger is connected to the outlet of the second dehydrator and connected to the heat generator to circulate the heat carrier through the gas exchanger, the output of which is connected to the dryer connected to the gas outlet the heat generator by the pipeline in which the mixer is installed, the return channel connected to the exhaust gas of the dryer, the output of which Knit with granulating device or briquetting dried product associated with the gas generator, the gas outlet through which cleaning and cooling device has connectivity to the electric current generator and / or a heat source. 4 s P. f-ly, 1 ill.

Description

The utility model relates to the field of equipment for processing waste having high humidity, for example, sewage sludge, sludge, manure and obtaining raw materials from them for the production of products, products themselves, and various types of fuel.

Currently, the problem of processing (utilization) of human and animal vital products is quite acute. Waste is processed to produce fertilizer from them (RF Pat. No. 2210550, 2264998, 2299872, 2316523), fuel (RF No. 2154666) or simply burned.

A very complex problem is the processing of waste products, which are biomass with a large number of components and having high humidity (up to 85%), which is typical for sewage sludge or manure.

A known installation for the treatment of sewage sludge, during which the water from the primary sumps falls into the aeration tank, after which the clarified water with sludge is fed into the distribution tank of activated sludge and then into the secondary sump. From the secondary sump, the purified water is supplied to the reservoir, and the sludge enters the distributor, where it is divided into streams: the first stream (activated sludge) is returned to the aeration tank via the return pipe; the second stream is fed into the aeration tank stabilizer; the third stream enters the seal, after which the compacted sludge enters the digester, where crude sludge from the primary settlers is simultaneously supplied. Fermented sludge enters the wash tank, where it is washed with industrial water. The washed precipitate is fed into the sealant, after which it is fed to the thickener and then to the filter press.

(see RF patent No. 2232135, class C02F 11/00, 2004).

As a result of the analysis of the implementation of this installation, it should be noted that it practically does not process the product, but only ensures the release of a homogeneous precipitate and the removal of only 12-15% of water from it. Thus, the known installation is characterized by very limited technological capabilities.

A known system for the treatment of sewage sludge containing a sludge dewatering unit associated with a drying and burning unit of dehydrated sludge, the first outlet of which is connected to a block for removing ash from flue gases and a flue gas treatment unit connected in series to it.

The second output of the drying and burning unit is connected to a steam collector, one output of which is connected to the steam recovery unit for heating the premises, and the other to the steam extraction unit.

The unit for removing ash from the flue gas is connected to the ash storage unit, including a loading hopper, connected in a way to a ball mill, the output of which is brought to the sludge pool.

The system also contains a storage module for raw materials (cement, lime, sand, water, foaming agent). The outputs of the containers with raw materials are connected with a dispenser, to which a conveyance from the sludge pool is connected. The dispenser output is also connected to a foam generator, which in turn is connected to an autoclave, where steam is supplied from the collector. The exit of the autoclave is connected with the storage of finished ash products.

During the operation of the system, the sludge is dehydrated and fed to the drying and incineration unit. In the combustion process, the resulting steam is used for space heating and fed to an autoclave. When burning a dehydrated sludge, flue gases are cleaned and removed to the atmosphere, and the ash is partially discharged to the place of its accumulation, and partially fed to the ash processing unit. In this unit, a homogeneous mixture of ash and water is obtained, which is fed to a dispenser, which also supplies raw materials in predetermined proportions,

additives and steam. The resulting ash-concrete mixture is used to prepare products that are subjected to autoclaving.

(see RF patent No. 2309129, class C02F 11/18, 2007).

As a result of the analysis of the implementation of the known system, it should be noted that, like the claimed one, it involves the removal of moisture from the mass (drying), burning of the dried sludge with the use of the obtained steam to ensure the functioning of the nodes and units of the system, and the use of the solid residue of sludge burning - ash, which collected in a hopper, crushed and sent to the module for manufacturing products from autoclaved ash-foam concrete. As a rule, these are building blocks.

However, the functioning of this system is associated with significant energy consumption. This is due to the fact that in the combustion unit, the sludge is burned, containing a significant amount of moisture not removed at the stage of product dehydration, which significantly increases the energy consumption of the product combustion process.

In addition, the implementation of this system does not involve the use of flue gases, which, after cleaning from the ashes, are emitted into the atmosphere.

Thus, this system, although it provides the processing of sewage sludge by burning it, obtaining ash and using it as a component for the production of ash concrete products that are used in construction, however, its implementation cannot be called optimal.

A known complex for the processing of organo-silty sludge of wastewater containing a platform equipped with several drains for supplying raw materials to be processed. The complex also contains a screw press connected by a conveyor to the platform. The screw press is designed to dewater the sludge and obtain pellets or briquettes from it. The exit of the screw press is connected to the drying chamber. The drying chamber is connected by a conveyor to the loading hopper of the pyrolysis unit equipped with a ring furnace, a prechamber with a gas

injection burner and fuel oil injection burner, as well as the unloading unit.

The gas-vapor output of the pyrolysis unit is associated with a cyclone. The complex also contains a series-connected refrigerator, scrubber, filter drop eliminator. The cyclone outlet is connected to the inlet of the refrigerator. The liquid fraction from the refrigerator, scrubber and filter is discharged into the sump, from which fuel oil is discharged into the tank. The gas outlet of the droplet eliminator is connected to a gas injection burner.

During the operation of the complex, wet sludge with a humidity of 80-90% is placed on the site, from where the partially dehydrated mass is fed to the screw press, where it is further dehydrated. When the mass is passed through molding holes, granules or briquettes are formed at the exit of the screw press, which are dried in a dryer. Dried raw materials are fed to the pyrolysis unit. The gas obtained during the pyrolysis is fed to the burner of the pyrolysis plant. Ash products of pyrolysis and coke are removed through an ash outlet to a storage tank. The solid residue of the pyrolysis process can then be used in metallurgy, water treatment, to obtain fertilizers and / or building materials. High-molecular hydrocarbons are condensed from the gas-vapor mixture and a fuel liquid is obtained.

(see RF patent No. 2239620, class C05F 7/00, 2004) is the closest analogue.

As a result of the analysis of the implementation of the known complex, it should be noted that it, as stated, provides the processing of silty sediments with a high moisture content (up to 90%). When this complex operates, the raw materials to be processed are pre-dehydrated at the site, and then granules or briquettes are formed on the screw press, which are finally dried in the drying chamber.

The obtained granules (briquettes) are disposed of in a pyrolysis unit, as a result of which, as in the claimed complex, combustible gas, liquid fuel and ash residue are obtained.

However, the implementation of this complex does not allow to obtain electrical energy from the gas component of the processing of sludge. In addition, the design of the known complex is very energy-intensive, since it involves drying not fine sludge, but granules or briquettes, which requires much higher heat consumption.

The problem solved by this utility model is the development of a complex for processing biomass with a high water content, low energy consumption, providing almost waste-free processing of biomass of various composition and moisture content, with the output of electric energy, heat and ash.

The task is ensured by the fact that in a biomass processing complex containing a biomass dehydrator, a dryer, a gas generator, an ash pan, the gas outlet of the generator is connected to a gas purification and cooling device, as well as transporting means for moving the processed biomass and products derived from it, the new one is the fact that the complex is equipped with a heat generator, at least one additional dehydrator, a device for granulating or briquetting dried biomass, dehydrators о are connected to each other, the heat exchanger is connected to the outlet of the second dehydrator and connected to the heat generator to circulate the heat carrier through the heat exchanger, the output of which is connected to the dryer connected to the gas outlet of the heat generator by a pipe in which the mixer is installed, which is connected by a return channel to the dryer gas outlet, the outlet of which is connected with a device for granulating or briquetting a dried product associated with a gas generator, the gas outlet of which through the cleaning and cooling device connection with an electric current generator and / or with a heat generator, the complex can be equipped with a mixer, the output of which is connected to the inlet of the first dehydrator, and conveyors for loading biomass and structurizer, and a third dehydrator installed between the heat exchanger and dryer are connected to the input, and second and third

dehydrators can be made vacuum type, while the second and third dehydrators can be connected to each other by a steam line.

When conducting patent research from the prior art, no solutions were identified that are identical to the claimed utility model, and therefore, it meets the eligibility condition “novelty”.

The design of components and assemblies used in the complex is known, it does not constitute the subject of patent protection and, therefore, is not disclosed in the materials of this application. To solve the problem for each node and unit of the complex, several well-known nodes and units can be used with approximately the same effect, the most preferred versions of some of which will be indicated in the materials of this application.

Relations in this application should be understood as conveyors, pipelines, conveyors, etc. The specific choice of communication for combining nodes and assemblies into a complex is determined by the condition and conditions of product transportation and does not pose difficulties for specialists.

Technological modes of product processing are characteristic for each specific unit of the complex and can be specified depending on the specific characteristics of the product, but do not go beyond the generally accepted.

Thus, the information presented in the application materials is quite sufficient for the practical implementation of the utility model by specialists.

The essence of the utility model is illustrated by graphic materials on which the scheme of the complex is presented.

The biomass processing complex in its most general design contains a mixer 1, to the input of which the biomass to be processed is fed through a conveyor 2. Biomass can be in the tank, on the site, fed from the sump.

The location of the biomass is indicated by the position 3. A conveyor 4 can also be brought to the inlet of the mixer for supplying a structuralizer to the mixer.

The output of the mixer 1 by means of a screw conveyor 5 is connected to the input of the first dehydrator 6. As a dehydrator, it is most expedient to use a dehydrator with a screw press and a vibrator placed on its body. Designs of such dehydrators are known. In the dehydrator there is a branch pipe 7 (for drainage of separated water). The outlet of the dehydrator 6 by the transporting means 8 is connected with the second dehydrator 9. As the second dehydrator, it is most advisable to use a vacuum type dehydrator. This dehydrator has a bypass pipe 10 to drain the water recovered from the product.

The output of the second dehydrator 9 by a conveyor (not indicated by the position) is connected to the input of the heat exchanger 11. The heat exchanger 11 is made in a known manner. So, for example, it can be made in the form of two pipes arranged in one another, along the inside of which the product is transported, and the coolant is circulated in the space between the pipes. To heat the coolant, a heat generator is used (for example, a grate furnace) 12, a piping system connected to the space between the pipes of the heat exchanger 11. The output of the heat exchanger 11 is connected to the third dehydrator 13 of the vacuum type, which is connected by a steam line 14 to the second dehydrator 9. The output of the third dehydrator is connected to the dryer inlet 15. The interior of the dryer is connected by a pipe 16 to the gas outlet of the heat generator 12. The gas outlet of the dryer 15 through the ash collector 17 is connected to the exhaust pipe (not the position nachenaet). The gas outlet of the dryer 15 through a pipe 18 is connected to a mixer 19 installed on the pipe 16. The dryer 15 is connected to a briquette installation 20 of the dried product. The output of the installation 20 by a conveyor (not indicated by the position) is connected to the gas generator 21. The gas output of the gas generator is connected to the cleaning device 22 and

cooling the resulting gas. This device is made in a known manner and there is no need for a detailed description of its design. After cleaning and cooling, the resulting gas can be sent to the consumer, fed to the heat generator 12 for combustion and / or served to a gas piston engine with an electric generator 23 to generate electric current. The ash residue of the gas generator 21 is connected to the ash pan 24.

The complex for biomass processing works as follows.

When the complex operates, the irrigated biomass, for example, the sediment from wastewater treatment with a moisture content of 50-85%, is conveyed by conveyor 2 to the mixer 1 from the place 3 of the sediment. By conveyor 4, a second component is fed into the mixer - a structurizer, which has a moisture content of 10-40% and a particle size distribution with particle sizes of not more than 20 mm. The structurer performs two functions: being mixed with wet biomass, it is concentrated by the screw in the dehydrator while moving the mixture near the inner surface of its body and serves as an updated filter for passing water from the biomass through openings outside the dehydrator body; increase in energy load in the dehydrated product.

After mixing the components loaded into the mixer 1, the mass is conveyed by the screw conveyor 5 to the dehydrator 6. In the dehydrator 6, due to the pressure created by the dehydrator screw and the vibration of the vibrator mounted on the dehydrator case, most of the water is removed from the mixture, which is discharged through the pipe 7 A partially dehydrated product is conveyed by conveyor 8 to a vacuum dehydrator 9. The water extracted from the product is discharged through pipe 10, and the product is conveyed by conveyor to heat exchanger 11.

The heat carrier circulating through the heat exchanger, generated by the heat generator 12, heats the product, which enters the vacuum dehydrator 13. From the heated product in the dehydrator 13, the moisture evaporates intensively and steam is supplied through the steam line 14 to the vacuum dehydrator 9 to heat the product located in it. Dehydrated

the product from the vacuum dehydrator 13 enters the dryer 15. The operation of the dryer is based on the supply through the pipeline 16 of flue gases from the heat generator 12, which dry the product moving inside the dryer. Part of the flue gas passes through the ash collector 17 and is discharged through the exhaust pipe into the atmosphere, and the other part of the flue gas is piped 18 to the mixer 19 to reduce the temperature of the flue gases coming from the heat generator 12 to the dryer. The dried product from the dryer is fed to the briquetting unit 20, from where the formed briquettes are fed either to the gas generator 21, or sent to the consumer.

The gas generator provides gasification of briquettes, which results in two products: generator gas and ash. The generator gas from the gas generator enters the device 22 for cleaning and cooling.

After cleaning and cooling, the generator gas can be supplied as fuel to a heat generator and / or to a gas engine with an electric generator 23 to generate an electric current. Ash is collected in ash pan 24 and sent for further processing.

When processing biomass with a relatively low water content, there is no need for a mixer and a third dehydrator.

The developed complex allows practically non-waste processing of biomass of high humidity to produce useful components, moreover, the thermal energy released during the operation of the complex is used for the needs of the complex, and the product sent to gasification in the gas generator has an increased energy content.

Claims (5)

1. A complex for processing biomass containing a biomass dehydrator, a dryer, a gas generator, an ash pan, a gas outlet of the generator is connected to a gas purification and cooling device, as well as transporting means for moving the processed biomass and products obtained from it, characterized in that the complex is equipped with a heat generator with at least one additional dehydrator, a device for granulating or briquetting dried biomass, dehydrators are connected in series with each other, a heat exchanger under it is connected to the outlet of the second dehydrator and is connected to the heat generator for circulating the heat carrier through the heat exchanger, the outlet of which is connected to the dryer connected to the gas outlet of the heat generator by a pipe in which a mixer is installed, the return channel connected to the dryer exhaust, the outlet of which is connected to the granulated or briquetted device of the dried product associated with the gas generator, the gas outlet of which through the cleaning and cooling device has the ability to connect to the generator electrically th current and / or with a heat generator. 2. The complex for processing biomass according to claim 1, characterized in that it is equipped with a mixer, the output of which is connected to the inlet of the first dehydrator, and conveyors for loading the biomass and structurizer are connected to the input. 3. The complex for processing biomass according to claim 1, characterized in that it is equipped with a third dehydrator installed between the heat exchanger and the dryer. 4. The complex for processing biomass according to claims 1 and 3, characterized in that the second and third dehydrators are made of vacuum type. 5. The complex for biomass processing according to claim 3, characterized in that the second and third dehydrators are connected to each other by a steam line.