RU2733791C1 - Method of microbiological processing of wet organomineral and weakly structured wastes of birds and device for its implementation - Google Patents

Abstract

FIELD: biotechnology.SUBSTANCE: method is proposed for microbiological processing of wet organomineral and weakly structured wastes of birds, including successive use of Pseudomonas sp. microbial cultures pre-dissolved in water at ratio of 1:2. RNCIM B-5060 and Azotobacter chroococcum RNCIM B-6010, taken in ratio of 2:1 with titre of each of them 10 cells/ml, and device for its implementation.EFFECT: inventions provide bioconversion of wet organomineral and weakly structured wastes of birds.2 cl, 23 dwg

Description

The invention relates to agriculture and can be used in the processing of waste from poultry farms.

Poultry farms are a significant source of environmental pollution. Flies and unpleasant odors, spreading over long distances from the dung, worsen the social and environmental conditions of life and work of poultry workers, as well as the health of animals forced to breathe ammonia vapors and other harmful fumes from sedimentation tanks and collection pits. The problem of recycling waste from poultry farms is also relevant because a large amount of arable land is occupied for their storage. Poultry farms are forced to pay heavy fines for environmental violations.

A known method of processing poultry droppings (wet organomineral and weakly structured substrates) using a biological product "Tamir" containing active saprophytic microorganisms (Zvezdin V.V. et al. Accelerated utilization of poultry manure and obtaining on its basis high-quality fertilizers by the method of biological treatment. technologies in Russia, Questions of practical application of microbiological preparations Baikal EM 1, Tamir and EM-Kurunga. Proceedings. - M .: 2004). At the exit from the poultry farm, the biological product "Tamir" was introduced into the manure, which is taken into the pits, and mixed 2 times during the day. Filling the pit takes 3 days, and natural mixing occurs. The cost of introducing and mixing the EM preparation in this case is less than when introducing it into the field using a tractor and a barrel. The bird droppings mixed with the biological product "Tamir" were taken out to the arable field, spread across the field in a thin layer.

The disadvantages of this method are high labor intensity, low productivity and deterioration of the social and environmental conditions of life and work of employees of poultry farms.

A known method for producing biofertilizers (RF patent No. 2542115, IPC C05F 3/00, C05F 11/08, publ.20.002.2015, bull. No. 5), including obtaining a biomixture by introducing a microbial culture of Pseudomonas sp. 114, deposited in VKPM under No. B-5060, and Azotobacter chroococcum B 35, deposited in VKPM under No. B-6010, with a titer of 10 ⁸ cells / ml in a ratio of 2: 1 on a dry combined carrier at the rate of 60 ml per 1 kg and mixing, characterized in that a cellulose-containing substance is used as a carrier, for example, sunflower or rice husk, and a mineral-containing component, for example perlite, taken in a ratio of 1: 3 by weight, then the biomixture is applied to the floor of poultry premises at a dose of 30-70 g per 1 m ² with a carrier humidity of 15-20%, then the biomixture with waste from poultry premises, as it accumulates, is collected and stored in piles.

The disadvantages of this method are high labor intensity, low productivity, deterioration of the social and ecological conditions of life and work of employees of poultry farms.

The closest analogue to the claimed technical solution is a method for microbiological processing of poultry droppings (RF patent No. 2437864, IPC (2009.01) C05F 3/00, C05F 11/08, publ. 27.12.2011, bul. No. 34), which consists in introducing a microbial culture Pseudomonas sp. 114, deposited in VKPM under No. В-5060, into poultry droppings with subsequent mixing, and then after 5 days add a microbial culture of Azotobacter chroococcum В 35 deposited in VKPM under No. В-6010, and mix again. The titer of the introduced microbial cultures was for Pseudomonas sp. 114-10 ⁸ cells / ml and for Azotobacter chroococcum B 35 10 ⁸ cells / ml. The volumetric ratio of the introduced cultures is 2: 1, respectively, at the rate of 45 ml per 1 kg of poultry manure with no litter keeping of poultry. When poultry litter Pseudomonas sp. 114 and Azotobacter chroococcum B 35, taken in a 2: 1 ratio, are applied in an amount of 15 ml per 1 kg of manure. Before introducing microbial cultures, each of them is diluted with water in a ratio of 1: 2, respectively.

The disadvantages of this method are low productivity, significant release of biogas, which worsens the environmental situation in the surrounding area, high labor costs.

The technical result is to increase productivity, improve the environmental situation by utilizing biogas for further processing, and reducing labor costs.

The technical result is achieved by the fact that in the method of microbiological processing of moist organomineral and weakly structured substrates and a device for its implementation using a microbial culture of Pseudomonas sp. 114, deposited in VKPM under No. В-5060, and Azotobacter chroococcum В 35, deposited in VKPM under No. В-6010, taken in a ratio of 2: 1 with a titer of each of them 10 ⁸ cells / ml, each of which is preliminary diluted in water in a ratio of 1: 2, respectively, and microbial cultures are introduced into moist organomineral and weakly structured substrates sequentially, starting with the introduction of Pseudomonas sp. 114 followed by stirring, after 5 days - Azotobacter chroococcum B 35 and stirring, while, with no bedding, for example, poultry, microbial cultures of Pseudomonas sp. 114 and Azotobacter chroococcum B 35 are introduced in the amount of 45 ml per 1 kg of moist organic and weakly structured substrates with litter keeping, for example, birds, microbial cultures of Pseudomonas sp. 114 and Azotobacter chroococcum B 35 are introduced in an amount of 15 ml per 1 kg of moist organomineral and weakly structured substrates, moist organomineral and weakly structured substrates, together with the microbial culture of Pseudomonas sp. 114. deposited in VKPM under No. V-5060 (hereinafter the first mass of the load) is fed through the first means for loading in a continuous flow into the rotating upper screw container of the device for implementing the method, where the first mass of the load is simultaneously mixed and transported along its horizontal axis, then the first load mass is transferred to the downstream rotating screw container, where further mixing and transportation in the opposite direction is carried out, then the first load weight is transferred to the downstream rotating screw container, into which Azotobacter chroococcum B 35 deposited in VKPM is fed through the second loading device under No. В-6010 (hereinafter the second mass of the load taken in a ratio of 2: 1 with a titer of each of them 10 ⁸ cells / ml each of which is previously diluted in water in a ratio of 1: 2, respectively) and mixed with the first mass of the load to form a mixture moist organomineral x and weakly structured substrates with microbial cultures and at the same time transport this mixture along the lower horizontal axis of the rotating screw container, then it is transferred successively to the rotating screw containers located below each other, while heated air is supplied to the inside of the lower rotating screw container towards the moving flows of the mixture, which, through the upper opening in the housing of the device, removes biogas for their further utilization and processing, the technical result is also achieved by the fact that in the device for microbiological processing of moist organomineral and weakly structured substrates, containing a vibrating housing equipped with a drive with a vibrator fixed from the bottom of the housing, elastically mounted on the base and hood for utilization of biogas mounted rotating screw containers with screw grooves in the inner perimeter, made of three rectangular strips bent alternately in opposite directions f sides at an angle of 140 ° along notches made at an angle of 60 ° to each other and to the longitudinal edges of the strips with the formation of equilateral triangles along the length of the strip, alternating in opposite directions, while the strips are connected to one another along the longitudinal edges at an angle of 70 ° with the formation along the inner perimeter of three broken curved helical surfaces and three broken helical grooves in the main direction for moving a mixture of moist organomineral and weakly structured substrates and microbial additives, as well as two broken curved helical surfaces and two helical grooves in the opposite direction for moving a mixture of moist organomineral and weakly structured substrates and microbial additives from loading to unloading, and three broken helical lines of the main direction with a pitch S and two broken helical lines of the opposite direction with a pitch of 0.25S are formed along the outer diameter of the screw container at the break points of the helical lines , in which the points of convergence of the sides of six equilateral triangles are located, while the screw containers are mounted horizontally in the device case under each other in a zigzag manner at an angle of 45 ° and connected to each other in a single technological chain using side covers that overlap and connect on one side of the end the walls of the device body, the outlets of the odd rotating screw containers with the inlets of the underlying even rotating screw containers, and on the other side of the end wall of the device body connect the outlets of the even rotating screw containers with the underlying odd rotating screw containers, while all odd rotating screw containers are equipped with perimeter with three helical grooves of the right main direction, and all even rotating screw containers are provided with three helical grooves of the left main direction, and they all rotate in the same direction, providing continuous movement of ma ss loading from top to bottom, from loading to unloading, in a zigzag manner inside rotating screw containers from one end wall of the device body to the opposite end wall of the device body, and the device body is equipped from above with an exhaust for utilizing biogas, from the bottom - with a slide for removing the finished product outside the vibrating body of the device , and the device is equipped with the first means for loading moist organic and weakly structured substrates together with the microbial culture of Pseudomonas sp. 114. deposited in VKPM under No. В-5060 inside the first rotating screw container located on top of the device body and the second means for loading Azotobacter chroococcum В 35, deposited in VKPM under No. В-6010 inside the lower third rotating screw container, while inside the lower of the rotating screw tank, an air supply pipeline is installed to impart movement to biogas along the zigzag-shaped cavities of the rotating screw tanks from bottom to top to the hood for biogas utilization.

According to the data of the patent-technical literature, a technical solution similar to the one claimed was not found, which makes it possible to judge the inventive level of the proposed method for microbiological processing of moist organomineral and semi-structured substrates and a device for its implementation

The novelty lies in the fact that the technological process in the device is carried out in a continuous flow, thus ensuring not only mixing of moist organomineral and weakly structured substrates with microbial cultures and their transportation from loading to unloading, but also technological movement-mixing by joint action on the mixture of moist organomineral and of weakly structured substrates and microbial cultures superimposed on each other of low-frequency oscillations with a large amplitude and high-frequency oscillations with a small amplitude, which reduces labor costs, increases productivity, accelerates bioconversion processes with a simultaneous increase in the biological activity of the processed product, ensures the utilization of biogas for its further processing, which improves environmental the situation in the surrounding areas.

The novelty of the invention lies in the fact that moist organomineral and poorly structured substrates, together with the microbial culture of Pseudomonas sp. 114. deposited in VKPM under No. V-5060 (hereinafter the first mass of the load) is fed through the first means for loading in a continuous flow into the rotating upper screw container of the device for implementing the method, where simultaneous mixing and transportation of the first mass of the load along its horizontal axis is performed, then the first mass of the charge is transferred to the downstream rotating screw container, where further mixing and transportation in the opposite direction is carried out, then the first weight of the charge is transferred to the downstream rotating screw container, into which Azotobacter chroococcum B 35 deposited in VKPM under No. В-6010, and mix with the first mass of the load and simultaneously transport this mixture along the lower horizontal axis of the rotating screw container, then it is transferred sequentially to the rotating screw containers located below each other, which accelerates bioconversion processes with a simultaneous increase in the biological activity of the processed product and reduces labor costs.

The novelty lies in the fact that air is supplied to the inside of the lower rotating screw container, towards the moving mixture flows, which removes biogas through the upper opening in the device body for their further utilization and processing, which improves the environmental situation in the surrounding area.

The novelty also lies in the fact that air is supplied to the inside of the lower rotating screw container, towards the moving flows of the mixture, which, due to the circulating air flows, accelerates the aerobic fermentation of the mixture of moist organomineral and weakly structured substrates and microbial cultures with their active mixing, and the bioconversion processes are accelerated with simultaneous an increase in the biological activity of the processed product.

The novelty lies in the fact that the device for microbiological processing of wet organomineral and weakly structured substrates contains a vibrating body equipped with a drive with a vibrator fixed from the bottom of the body, elastically installed on the base, this gives the wet organomineral and low-structured substrates and microbial cultures high-frequency vibrations with a low amplitude, which accelerates the processes bioconversion with a simultaneous increase in the biological activity of the processed product and increases productivity.

The novelty also lies in the fact that the device for microbiological processing of moist organomineral and weakly structured substrates is equipped with an extractor for utilizing biogas, this not only provides a discharge through the upper opening in the housing of the biogas device for further utilization and processing, which also improves the environmental situation in the surrounding area and produces utilization of biogas for further processing, but also accelerates the processes of bioconversion with a simultaneous increase in the biological activity of the processed product and increases productivity by increasing the speed of air movement and increasing the area of its contact with a moving mixture of moist organomineral and weakly structured substrates and microbial cultures.

The novelty lies in the fact that rotating screw containers with screw grooves in the inner perimeter, made of three strips bent in straight lines at an angle of 60 ° to the edges of the strips, are mounted in the vibrating housing of the device for microbiological processing of moist organic-mineral and weakly structured substrates, with the formation of equilateral triangles located on the strip alternately to one another in opposite directions at an angle of 140 °, while the strips are connected to each other along the longitudinal edges at an angle of 70 °, with the formation of three broken helical lines along the outer perimeter of the rotating screw container, at the break points of which six the tops of equilateral triangles and along the inner perimeter of three helical grooves in the main direction and two helical grooves in the opposite direction, which not only gives the longitudinal movement of the mixture of moist organomineral and weakly structured substrates and microbial cultures from loading to unloading, but also at the same time imparts to this mixture a movement inside the screw containers with a large amplitude and low frequency, which in turn accelerates the bioconversion processes with a simultaneous increase in the biological activity of the processed product and increases productivity.

The novelty also lies in the fact that such a structural design of the device body provides not only transport movement of a mixture of moist organomineral and weakly structured substrates and microbial cultures inside screw containers from loading to unloading, but also technological movement - mixing and giving this mixture superimposed low-frequency vibrations with a large amplitude and high-frequency oscillations with a small amplitude, which increases productivity and accelerates the processes of bioconversion with a simultaneous increase in the biological activity of the processed product, as well as the utilization of biogas for its further processing, which improves the ecological situation in the adjacent territories.

The novelty lies in the fact that the screw containers are mounted horizontally in the body of the device, one under the other, in a zigzag manner, at an angle of 45 °, which interferes with the dimensions of the device in height and labor costs.

The novelty lies in the fact that the screw containers are connected to each other in a single technological chain with the help of side covers that overlap and connect on one side of the end wall of the device body the outlets of odd rotating screw containers with the inlets of the underlying even rotating screw containers, and on the other the sides of the end wall of the device body connect the outlet openings of the even rotating screw containers with the underlying odd rotating screw containers, while all odd rotating screw containers are provided along the perimeter with three screw grooves of the right main direction, and all even rotating screw containers are equipped with three screw grooves of the left main direction and they all rotate in the same direction, providing continuous movement of the loading masses from top to bottom, from loading to unloading, in a zigzag manner inside rotating screw containers from one end wall of the device body to the opposite t the end wall of the device body, and the device body is equipped from above with an exhaust for utilizing biogas, from the bottom - with a slime for removing the finished product outside the vibrating body of the device, and is equipped with a first loading device for moist organomineral and weakly structured substrates together with a microbial culture of Pseudomonas sp. 114. deposited in VKPM under No. В-5060 inside the first rotating screw container located on top of the device casing and the second means for loading Azotobacter chroococcum В 35, deposited in VKPM under No. В-6010 inside the lower third rotating screw container, which will interfere with the dimensions of the device. height and labor costs.

The essence of the invention is illustrated by drawings, where FIG. 1 shows a device for implementing a method for microbiological processing of wet organomineral and weakly structured substrates in section A-A in FIG. 2, general view; in fig. 2- section b-b in Fig. 1; in fig. 3- view A in FIG. 1; in fig. - view B in Fig. 4; in fig. 5 - section b-b in fig. 3; in fig. 6 - section Г-Г in FIG. 3 as a diagram of the movement of moist organomineral and semi-structured substrates and microbial cultures from loading to unloading; Fig. 7 is a cross-sectional view G-G in Fig. 3 in the form of a diagram of air movement from bottom to top and discharge of biogas into the body of the device and supplying it to the hood and discharge outside the body; in fig. 8 - a rotating screw container, assembled from three strips (lines - the longitudinal edges of the connection of the strips are shown by a thickened line) in Fig. 9 is a view D in FIG. 8; in fig. 10 - section e-d in Fig. 8; in fig. 11 - one of three stripes with marked fold lines; in fig. 12 - section E-E in Fig. eleven; in fig. 13 - one of three strips after rolling around its axis; in fig. 14 - one of three strips rolled around a cylindrical mandrel; in fig. 15 - section Zh-Zh in Fig. fourteen; in fig. 16 - external section 1 in Fig. 8; in fig. 17 - section 3-3 in Fig. 8; in fig. 18 - section AND in Fig. 8; Fig. 19 is a section K-K in Fig. 8; in fig. 20 - section L-L in Fig. 8; in fig. 21 - external section P in Fig. 7; Fig. 22 is a remote section W in Fig. 7; in fig. 23 is a view E in FIG. 22

Method for microbiological processing of moist organomineral and weakly structured substrates

is carried out as follows.

As moist organomineral and

wastes of birds were taken from weakly structured substrates.

Wet organomineral and weakly structured substrates with a microbial culture of Pseudomonas sp. 114, deposited in VKPM under No. B-5060, and Azotobacter chroococcum B 35, deposited in VKPM under No. B-6010, (hereinafter the first mass of the load, taken in a ratio of 2: 1 with a titer of each of them 10 ⁸ cells / ml, each of which is preliminarily diluted in water in a ratio of 1: 2, respectively, and microbial cultures are introduced into moist organomineral and weakly structured substrates sequentially), fed through the first means for loading 21 in a continuous flow into the upper first rotating screw container 6, where simultaneous mixing and transportation is carried out the first load mass along its horizontal axis, then the first load mass is transferred to the downstream second rotating screw container 7, where further mixing and transportation in the opposite direction is carried out, then the first load mass is transferred to the lower third rotating screw container 8, into which, through second loading medium 22 serves Azotob acter chroococcum В 35, deposited in VKPM under No. В-6010 (hereinafter the second mass of the load, taken in a ratio of 2: 1 with a titer of each of them 10 ⁸ cells / ml, each of which is previously diluted in water in a ratio of 1: 2, respectively ,). At the same time, with no bedding, for example, birds, microbial cultures of Pseudomonas sp. 114 and Azotobacter chroococcum B 35 are introduced in an amount of 45 ml per 1 kg of moist organic and weakly structured substrates, with litter keeping, for example, poultry, microbial cultures of Pseudomonas sp. 114 and Azotobacter chroococcum B 35 are introduced in an amount of 15 ml per 1 kg of moist organic mineral and weakly structured substrates. In the third rotating screw container 8, the second mass of the load is mixed with the first mass of the load and a mixture of moist organomineral and weakly structured substrates with microbial cultures is formed, which is simultaneously transported along the lower horizontal axis of the third rotating screw container 8. Then the mixture is transferred successively to the rotating screw containers located below each other. containers 9, 10, 11, 12, 13. In the process of transporting moist organomineral and semi-structured substrates and microbial cultures from loading to unloading in zigzag mounted rotating screw containers 6, 7, 8, 9, 10, 11, 12, 13, the wet organomineral and weakly structured substrates with microbial culture and bioconversion. Aerobic fermentation of a mixture of moist organomineral and weakly structured substrates with a microbial culture during stirring is also facilitated by the supply of air inside the last lower rotating screw container 13 by pipeline 27. When air moves along the zigzag-like cavities of rotating screw containers 6, 7, 8, 9, 10, 11, 12, 13 from bottom to top, as well as with the help of exhaust 23, biogas is removed outside the device. Simultaneous transport movement of a mixture of wet organomineral and semi-structured substrates and microbial cultures inside screw containers 6, 7, 8, 9, 10, 11, 12, 13 from loading to unloading and the technological movement (mixing) of the mixture is performed under the influence of superimposed low-frequency vibrations with a large amplitude (created inside the screw containers 6, 7, 8, 9, 10, 11, 12, 13 by their geometry and high-frequency vibrations with a small amplitude (created by vibrator 5) increases productivity and accelerates bioconversion processes with a simultaneous increase in the biological activity of the processed product. From the last lower rotating screw container 13, the finished product enters the slime 24 and is subsequently discharged into the container 30.

The technical and economic advantages of the proposed method arise due to increased productivity as a result of exposure to circulating air flows and acceleration of aerobic fermentation of a mixture of moist organomineral and weakly structured substrates and microbial cultures with their active mixing, reducing labor costs by performing microbiological processing of moist organomineral and weakly structured substrates in one device , improving the ecological situation by utilizing biogas for its further processing.

Patent research was carried out in this direction - no analogs of the device were found.

A device for implementing a method for microbiological processing of wet organomineral and weakly structured substrates (Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5), consists of a housing 1 mounted on a plate 2, elastically mounted on the base 3 with the help four elastic elements 4. A vibrator is attached to the plate 2 at the bottom 5. Inside the housing 1, horizontally rotating screw containers 6, 7, 8, 9, 10, 11, 12, 13 are mounted under each other in a zigzag manner at an angle of 45 ° and connected to each other in a single technological chain using side covers 14, 15, 16 and 17, 18, 19, 20, which overlap and connect on one side of the end wall of the housing 1 of the device, the outlet openings of the even rotating screw containers 6, 8, 10, 12 with the inlet openings of the underlying odd rotating screw containers 7, 9, 11, 13, and on the other side of the end wall of the device body connect the outlet openings of the odd rotating screw containers 7, 9, 11, 13 with the underlying even rotating screw containers 6, 8, 10, 12. The device is equipped with a first means for loading 21 poultry droppings together with a microbial culture of Pseudomonas sp. 114. deposited in VKPM under No. В-5060 inside the first rotating screw container 6 located on top of the housing 1 and the second means for loading 22 Azotobacter chroococcum В 35 deposited in VKPM under No. В-6010 inwardly below the third rotating screw container 8. The body 1 is equipped from above with an exhaust 23 for utilizing biogas, from below - with a slime 24 for removing the finished product outside the housing 1. The odd rotating screw containers 7, 9, 11, 13 are equipped along the perimeter with three screw grooves of the right main direction, and the even rotating screw containers 6, 8, 10, 12 are provided with three screw grooves of the left main direction and they all rotate in the same direction, providing continuous movement of the loading masses from top to bottom, from loading to unloading, in a zigzag manner inside the rotating screw containers 6, 7, 8, 9, 10, 11, 12, 13 from one end wall 25 of the housing 1 to the opposite end wall 26 of the housing 1 (Fig. 1, Fig. 6).

Inside the lower rotating screw container 13, a pipeline 27 for supplying warm air is mounted to impart movement to biogas along the zigzag-like cavities of rotating screw containers 6, 7, 8, 9, 10, 11, 12, 13 from the bottom up to the hood for utilizing biogas 23 (Fig. 7 ).

The device is equipped with a motor 28 for rotating screw containers 6, 7, 8, 9, 10, 11, 12, 13. Rotation from the motor 28 is transmitted by means of a chain transmission 29 to even screw containers 12, 10, 8, 6 and from them to odd screw containers 7, 9, 11, 13 (Fig. 2). The device is equipped with a container 30 for receiving finished products. Inside the housing 1, between the end walls 25 and 26, a slip 31 is mounted in the form of a partition, which exits through the opening 32 in the housing 1. The device is equipped with a container 33.

Screw containers 6, 7, 8, 9, 10, 11, 12, 13 (Fig. 8, Fig. 9) are made of three rectangular strips 34, 35, 36 with the formation along the perimeter along the outer diameter of the screw container, for example 6, three screw lines 37-38-39-40-41-42; 43-44-45-46-47; 48-49-50-51-52, and along the inner diameter of three broken helical grooves K] - 37-38-39-40-41-42; K ₂ - 43-44-45-46-47; K ₃ - 47-48-49-50-51-52 with an internal angle of 70 ° (Fig. 10). On all strips 34, 35, 36 (Fig. I, Fig. 12) at an angle of 60 ° to the longitudinal edges 53 and 54, cuts 55, 56 are made alternately from opposite sides with beveled walls (Fig. 12), arranged in pairs at an angle of one to the other by milling, pressure working, etc., to form equilateral triangles 57.

The geometry and values of the angles λ, ϕ, ω, ψ, α, β of the bevels of the notches 55, 56 (Fig. 11, Fig. 12) and their relative position determine the angles of inclination of equilateral triangles 57 to each other along the perimeter of the screw container 6. Strips 34 , 35, 36 are rolled in a vertical plane (Fig. 13) in the longitudinal direction relative to the strip's own axis of symmetry, and then bent along helical lines in the transverse direction (Fig. 14) and bent along incisions 55, 56 with beveled walls in the transverse longitudinal direction disposed in pairs at an angle to one another on both sides of the strips, such as strips 34 in FIG. 11, fig. 12, figs. 13, fig. 14, figs. 15. In FIG. 13 shows one of the strips, for example 34, twisted in a vertical plane along its longitudinal axis with side edges 53 and 54. A strip previously twisted in a vertical plane relative to the longitudinal axis, for example 34, is placed on a shipment 58 (Fig. 14, Fig. 15) and bent so that the side edges 53 and 54 are positioned along helical lines in the transverse direction. After bending in the transverse direction, each of the strips 34, 35, 36 is rotated relative to the longitudinal axis of the screw container 6 so that their edges also form helical lines in the transverse direction of the strips with the same pitch for all strips. After that, strip 34 is removed from dispatch 58, or fixed on dispatch 58. The remaining strips, for example 35 and 36, are processed in the same way. After folding the strip, for example strip 34 (Fig. 11, Fig. 12, Fig. 13, Fig. 14) cuts 37-43, 43-38, 38-44, 44-39, 39-45, 45-40, 40-46, 46-41, 41-47, 47-42 are welded, resulting in stiffening ribs. The strips 34, 35, 36, after bending, are connected to one another along the longitudinal edges 53 and 54 at an angle of 70 ° (Fig. 8). Such a connection of three strips 34, 35, 36 becomes possible, since after folding the strips 34, 35, 36 along straight fold lines 55 and 56 (Fig. 11, Fig. 12) at an angle of 140 ° alternately to each other in opposite directions ( Fig. 8) on the strip 34, faces are formed in the form of equilateral triangles 57, located on the strip 34 alternately in opposite directions, with the formation along the longitudinal edges of the strips 34, 35, 36, more precisely along the perimeter of the outer diameter of the screw container 6 of three broken helical lines of the main direction 37-38-39-40-41-42; 43-44-45-46-47; 48-49-50-51-52 with a pitch S (Fig. 8), one of which is shown by a thickened line 37-38-39-40-41-42 in Fig. 8 and two broken helical lines in the opposite direction, one of which in FIG. 8 shows a thickened line 51-40-45-49-38 with a pitch of 0.25 S. FIG. 8 shows a thickened line 37-38-39-40-41-42 one of three broken helical lines of the main direction with a pitch S, in each of the break points of which at the vertices of the broken helical lines of the main direction (Fig. 8, Fig. 16) are the points of convergence of the sides of six equilateral triangles T ₁ , T ₂ , T ₃ , T ₄ , T ₅ , T ₆ . For example, at point 40 (Fig. 16), the sides 59, 60, 61, 62, 63, 64 of six equilateral triangles T ₁ , T ₂ , T ₃ , T ₄ , T ₅ , T ₆ converge. The joining of strips 34, 35, 36 can be carried out by known methods, for example by welding.

In the end wall 22 (Fig. 7) of the housing 1 there are holes 65, 66, 67, and in the end wall 23 there are holes 68, 69, 70, 71 for the biogas outlet from the screw containers 7, 8, 9, 10, 11, 12 , 13 inside the housing 1 and output them using the hood 23 for disposal. The shape of the holes 65, 66, 67, 68, 69, 70, 71 is shown by way of example in FIG. 21, figs. 22, figs. 23.

A device for microbiological processing of moist organomineral and weakly structured substrates works as follows.

By known methods and means, warm air is supplied through the pipeline 27 inside the screw container 13 and then upward (Fig. 5, Fig. 7). The hood 23 is turned on and then from the engine 28 by means of the chain drive 29 the screw containers 6, 7, 8, 9, 10, 11, 12, 13 are turned on. The vibrator is turned on 5. Wet organomineral and weakly structured substrates with the microbial culture of Pseudomonas sp. 114, deposited in VKPM under No. В-5060, and Azotobacter chroococcum В 35, deposited in VKPM under No. В-6010, taken in a ratio of 2: 1 with a titer of each of them 10 ⁸ cells / ml, each of which is preliminary diluted in water in a ratio of 1: 2, respectively, and microbial cultures are introduced into moist organomineral and weakly structured substrates sequentially, starting with the introduction of Pseudomonas sp. 114 in a continuous flow in the form of a mixture (hereinafter the first mass of the charge) is supplied to the first means for the charge 21 (Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5). From the first means for loading 21 the mixture (the first mass of loading) is transferred into the inner cavity of the screw container 6 rotating around its own axis. Three helical grooves of the left main direction 34-35-36-37-38-39; 40-41-42-43-44-45; 45-46-47-48-40-50 in the screw container 6 (Fig. 8) this mixture (the first mass of the charge) is transported from the load to the side cover 17 (Fig. 6). From the outlet of the screw container 6 through the space closed by the side cover 17, the mixture (the first mass of the charge) flows in a continuous flow into the inlet of the underlying screw container 7 and its three screw grooves of the right main direction is transported in the opposite direction to the side cover 14 (Fig. 6). Then, from the outlet of the rotating screw container 7, through the space closed by the side cover 14, the mixture (the first mass of the charge) flows in a continuous flow into the rotating screw container 8, where it is transported by three screw grooves in the opposite direction to the cover 18 (Fig. 6). The microbial culture Azotobacter chroococcum B 35 deposited in VKPM under No. B-6010 is introduced into the screw container 8 with the second means for loading 22 in a continuous flow, where it mixes with the first mass of the load, forming a second mixture - the second mass of the load, moving towards each other and then together ( second load mass) are moved to the side cover 18 (Fig. 6). Through the space closed by the side cover 18, the mixture (the second mass of the load) flows in a continuous flow into a rotating screw container 9, where it is transported by three screw grooves in the opposite direction to the side cover 15 (Fig. 6). Through the space closed by the side cover 15, the mixture (the second mass of the load) enters the rotating screw container 10 in a continuous flow, where its three screw grooves are transported in the opposite direction to the side cover 19 (Fig. 6). Then, through the space closed by the side cover 19, the mixture (the second mass of the load) flows in a continuous flow into the rotating screw container 11, where it is transported by three screw grooves in the opposite direction to the side cover 16 (Fig. 6). Then, through the space closed by the side cover 16, the mixture (the second mass of the charge) flows in a continuous flow into the rotating screw container 11, where it is transported by three screw grooves in the opposite direction to the side cover 20 (Fig. 6). Through the space closed by the side cover 20, the mixture (the second mass of the load) flows in a continuous flow into a rotating screw container 13, where it is transported by three screw grooves in the opposite direction to unloading, where it enters the slime 24 and is subsequently unloaded into the container 30 for receiving the finished product ( Fig. 6). The second loading device 22 is equipped with a screw tip with smooth screw surfaces, the branch pipe 27 is also made also screw with smooth screw surfaces. In the process of transporting wet organomineral and weakly structured substrates and microbial cultures from loading to unloading in zigzag mounted screw containers 6, 7, 8, 9, 10, 11, 12, 13, the wet organomineral and weakly structured substrates are mixed with the microbial culture and bioconverted. Aerobic fermentation of a mixture of moist organomineral and weakly structured substrates with a microbial culture during stirring is facilitated by the supply of air inside the lower rotating screw container 13, by an air pipeline 27 to impart movement to biogas along the zigzag-like cavities of rotating screw containers 6, 7, 8, 9, 10, 11 12, 13 from bottom to top to the hood 23 for utilizing biogas (Fig. 7).

The technical and economic advantages of the device arise due to the fact that the rotating containers 6, 7, 8, 9, 10, 11, 12, 13 are made of three helical strips with three smooth helical lines 37-38-39-40-41-42; 43-44-45-46-47; 48-49-50-51-52 along the outer perimeter and three helical grooves along the inner perimeter, mounted horizontally in the device body 1 under each other, in a zigzag manner, at an angle of 45 °, which reduces the dimensions of the device in height and provides a reduction in labor costs due to the implementation microbiological processing of wet organomineral and semi-structured substrates in one device, improving the ecological situation by utilizing biogas for its further processing not only by means of an extract 23, but also by making holes 65, 66, 67, 68, 69 in the end walls of the body 1, 70, 71 for removing biogas from screw tanks 7, 8, 9, 10, 11, 12, 13 inside the housing 1.

Claims (2)

1. Method for microbiological processing of wet organomineral and semi-structured waste of vital activity of birds using microbial cultures of Pseudomonas sp. VKPM B-5060 and Azotobacter chroococcum VKPM B-6010, taken in a ratio of 2: 1 with a titer of each of them 10 ⁸ cells / ml, previously diluted in water in a ratio of 1: 2 and introduced sequentially, characterized in that the processing is carried out in the device , into which through the first means for loading the waste is fed in a continuous flow together with the microbial culture of Pseudomonas sp. VKPM B-5060 - the first load mass - into the rotating upper screw container of the processing device with stirring and transporting it along the horizontal axis and then into the rotating screw container located below, then the second load of Azotobacter chroococcum VKPM V-6010 is fed through the second loading device, mixed with the first mass of the charge and this mixture is transferred to the rotating screw containers located one under the other, while heated air is supplied to the inside of the lower rotating screw container towards the moving flows of the mixture to remove biogas. 2. A device for microbiological processing of wet organomineral and semi-structured waste of the vital activity of birds using microbial cultures of Pseudomonas sp. VKPM B-5060 and Azotobacter chroococcum VKPM B-6010, taken in a ratio of 2: 1 at a titer of each of them 10 ⁸ cells / ml, preliminarily diluted in water in a ratio of 1: 2 and introduced in series, characterized in that it contains a vibrating housing with a vibrator fixed from below, resiliently mounted on the base, on which are mounted rotating screw containers with helical grooves along the inner perimeter, made of three rectangular strips bent alternately in opposite directions at an angle of 140 ° along incisions made at an angle of 60 ° to each other and to the longitudinal edges of the strips with the formation along the length of the strip of equilateral triangles arranged alternately in opposite directions, while the strips are connected to one another along the longitudinal edges at an angle of 70 ° to form three broken curved helical surfaces and three broken helical grooves of the main direction along the inner perimeter for moving a mixture of moist organomineral and labostructured waste of the vital activity of birds, as well as two broken curved helical surfaces and two helical grooves in the opposite direction for its movement from loading to unloading, while the screw containers, mounted horizontally in the device body, are located under each other in a zigzag manner at an angle of 45 ° and connected to each other the other into a single technological chain with the help of side covers that overlap and connect on one side of the end wall of the device body the outlets of the odd rotating screw containers with the inlets of the underlying even rotating screw containers, and on the other side of the end wall of the device body connect the outlets of the even rotating screw containers with underlying odd rotating screw containers, while all odd rotating screw containers are provided along the perimeter with three screw grooves of the right main direction, and all even rotating screw containers are equipped with three helical grooves of the left main direction, and all of them are installed with the ability to rotate in one direction, providing continuous movement of the loading masses from top to bottom, from loading to unloading, in a zigzag manner inside rotating screw containers from one end wall of the device body to the opposite end wall of the device body, and the body of the device is provided with a slime from the bottom to remove the finished product outside the vibrating body of the device, and the device is also equipped with the first means for loading wet organomineral and semi-structured waste from birds with a microbial culture of Pseudomonas sp. VKPM B-5060 inside the first rotating screw container located on top of the device body and the second means for loading Azotobacter chroococcum VKPM B-6010 inside the lower third rotating screw container, while inside the lower rotating screw container there is an air supply pipeline to impart movement to biogas in a zigzag cavities of rotating screw containers from bottom to top to the hood for biogas utilization.

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