RU133829U1 - INSTALLATION FOR ANAEROBIC PROCESSING OF ORGANIC WASTE - Google Patents

Abstract

Installation for anaerobic processing of organic waste of animal and vegetable origin, production of biogas and liquid organic fertilizer, containing a bioreactor with a biomass heater, made in the form of a sealed cylindrical container with a gap with it and between each other, according to the principle of "nested dolls" containers , a system for supplying preheated and ground raw materials, a system for intensive mixing of biomass, a system for removing biogas from a reactor with a vacuum pump, a system for systematic way process, the finished product discharge and filling system, characterized in that the preheating of the feedstock system is configured as a coil installed in the preheating vessel and mixing raw material and in communication with the bioreactor.

Description

The inventive utility model relates to the field of agriculture and can be used for anaerobic processing of organic waste of animal and vegetable origin, biogas production and preparation of fertilizers from animal manure and agricultural waste.

A technical solution is known according to the patent of the Russian Federation No. 2315721, IPC С02F 3/28, С02F 11/04, dated 03.04.2006, in which the hermetically sealed container is divided by means of vertical partitions communicating with each other, a set of overflow partitions installed at different heights relative to the bottom bioreactor bodies and liquid mirrors in it.

There is also a technical solution according to RF patent No. 2056393, "Installation for the processing of animal waste and fertilizer production", IPC C05F 3/06, 03/19/1993, containing blocks of neutralization and purification, compression and storage of gas. The distinctive features of this solution include the presence of a gas-liquid ejector on the feed line of the heated manure, and an airlift bubbler is installed in the digester. The disadvantages of this solution include a large number of bulky equipment and the presence of a solid fraction after the end of the processing cycle.

Closest to the claimed installation according to the technical essence can be attributed to "Installation for anaerobic processing of organic waste of animal and vegetable origin, the production of biogas and liquid organic fertilizer".

The plant for anaerobic processing of organic waste of animal and vegetable origin, contains a bioreactor with a biomass heater, a feed system for preheated and ground raw materials, a system for intensive mixing of biomass, a system for removing biogas from a reactor with a vacuum pump, a process control system, a finished discharge and bottling system product, the bioreactor of the installation is made in the form of a sealed container of cylindrical shape with placed in it, with a gap with it and between y is, on a "nested dolls" capacitances, the bioreactor is provided with additional lateral impeller set at an angle λ ° relative to the horizon.

This technical solution was taken for the closest analogue (prototype).

The disadvantages of this technical solution include the fact that in a known installation, preheating of the feedstock is carried out naturally.

The objective of the proposed technical solution is to increase the productivity and reliability of the installation with a continuous process.

The proposed technical solution contains a bioreactor with a biomass heater, made in the form of a sealed cylindrical container with a gap in it and with each other, according to the principle of "matryoshka" containers, a feed system for preheated and ground raw materials, a system for intensive mixing of biomass, a biogas removal system from a reactor with a vacuum pump, a process control system and a finished product unloading and bottling system.

Distinctive features of the proposed technical solution is the following:

- the system of preheating of the feedstock is made in the form of a coil installed in the tank for preheating and mixing the feedstock and communicating with the bioreactor.

Analysis of the set of essential features of the claimed technical solution, ensuring its difference from the known solutions, indicates the compliance of this solution with the criterion of "NOVELTY."

The possibility of implementing the inventive utility model and its use in anaerobic processing of organic waste of plant and animal origin, the production of biogas and liquid organic fertilizer indicates the compliance of this decision with the criterion "INDUSTRIAL APPLICABILITY".

The essence of the proposed technical solution is illustrated by drawings, which depict:

- figure 1 - installation for anaerobic processing of organic waste of animal and vegetable origin, the production of biogas and liquid organic fertilizer;

Installation for anaerobic processing of organic waste of animal and vegetable origin, the production of biogas and liquid organic fertilizer contains a receiving hopper 1, a container 2 for mixing and preheating the waste, a container 3 with a water trap, a bioreactor 4, a side mixer 5, installed at an angle λ relative to the horizon. The installation has several pumps that ensure the continuity of the process: a vacuum pump 6 for pumping biogas from the bioreactor 4, a submersible pump 7 with a grinder for mixing and supplying raw materials from the receiving hopper 1 to the preparation tank 2, a submersible pump 8 with a grinder for mixing, feeding raw materials from preparatory tank 2 into the reactor 4, a submersible pump 9 for the system of preheating of raw materials and pumping out the finished fertilizer, pumps 10, 11, 12 for intensive mixing, creating the rotational movement of the entire bi mass counterclockwise and break the surface crust of biomass in tanks A, B, C, D, placed on a "nested dolls" in bioreactor 4. Gas boiler 13 working biogas produced by the unit, the control unit 14 installation. Heat exchangers 15 and 16, respectively, of tanks A and B, thermal insulation 17 of the bioreactor 4, inspection hatch 18, the filling line of the finished product 19, coil 20 for preheating the feedstock.

Capacity A is mounted from the bottom of the bioreactor 4, with an excess of liquid in it and not reaching the cover of the bioreactor 4, while container A has a heat exchanger 15 in the cavity of which the coolant (water) is circulated heated by a gas boiler 13, and in the lower part of the tank And there are windows for the passage of biomass into tank B (not shown in the drawing).

Capacity B is mounted from the bottom of the bioreactor 4, with an excess of liquid in it above the mirror and not reaching the lid of the bioreactor 4. Capacity B has a heat exchanger 16 in the cavity of which the coolant (water) circulates.

The tank C is mounted with a non-return to the bottom of the bioreactor 4, and its upper part is the cover of the bioreactor 4 with thermal insulation 17.

Capacity D is the outer cylinder of the bioreactor 4 with heat insulation 17 and the inspection hatch 18. An additional side mixer 5 is mounted in the outer cylinder of the bioreactor 4, which is installed at an angle λ relative to the horizon.

Installation works as follows:

upon receipt of the feedstock diluted with water in the receiving hopper 1, the pump 7 is turned on, mixes and crushes the feedstock, feeds it to the preparatory tank 2. Tank 2 is pre-filled to 1/3 with fermented, warmed up, using a coil 20, feedstock for preliminary insemination of the feedstock . The coil 20 communicates with the bioreactor 4. Then the pump 8 is turned on, which mixes, crushes and feeds the raw material into the tank A of the bioreactor 4. Subsequent batches of the feedstock are prepared in the same way.

The capacity A of the bioreactor 4 is gradually filled and with it the capacity B is filled through the windows in the lower part of the capacity A. At the same time, the incoming raw material is heated by heat exchangers 15 and 16.

Having reached the upper edge of the container B, the raw material is poured into the container C and at the same time fills the containers C and D.

Upon reaching the required level in tanks C and D, the feed process stops, the fermentation process begins with vigorous stirring by pumps 10, 11, 12 and an additional side mixer 5. Heat exchangers 15 and 16 using a gas boiler 13 raise the temperature of the feed to 30-40 degrees (mesophilic phase of the process), at which the release of biogas begins. The vacuum pump 6 is turned on, which pumps the biogas obtained from the bioreactor 4 and delivers it to the gas boiler 13 to maintain the desired temperature in the bioreactor 4, providing the necessary vacuum parameters. A further increase in the temperature of the raw material transfers the process of its processing from the mesophilic to the thermophilic phase. The thermophilic mode of operation of the bioreactor 4 occurs at a temperature of 52-54 degrees. At the end of the fermentation process, the loading of the feedstock into the tank A is resumed, and the finished fertilizer from the tank D into the tank 3, from where it is fed to the filling line 19 with simultaneous heating of the feedstock using a coil 20 in the preparation tank 2.

The use of this technical solution - installation for anaerobic processing of organic waste of animal and vegetable origin, the production of biogas and liquid organic fertilizer, allowed to increase its productivity and reliability with the continuity of the process.

Claims (1)

Installation for anaerobic processing of organic waste of animal and vegetable origin, the production of biogas and liquid organic fertilizer, containing a bioreactor with a biomass heater, made in the form of a sealed cylindrical container with a gap with it and between each other, according to the principle of "nested dolls" containers , a system for supplying preheated and ground raw materials, a system for intensive mixing of biomass, a system for removing biogas from a reactor with a vacuum pump, a system for systematic way process, the finished product discharge and filling system, characterized in that the preheating of the feedstock system is configured as a coil installed in the preheating vessel and mixing raw material and in communication with the bioreactor.

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