MD632Z - Plant for the production of vermiculture and vermicompost and vermicompost extractor - Google Patents

Abstract

The invention relates to the production technology of vermiculture and vermicompost by processing the plant residues of the agro-industrial complex, food and fishing industries, as well as inorganic waste.The plant for the production of vermiculture and vermicompost consists of at least one module, which includes a reservoir for the substrate, vermiculture and vermicompost, made in the form of a rigid modular construction, consisting of vertical central and lateral mountings (2), on which are fixed side frames (1), fastened by means of brace rods (3), and bearing angle pieces (5), on which are mounted thrust frames (8), on which is placed a grid (11). To the side frames (1), vertical lateral mountings (2) and bearing angle pieces (5) are attached with the possibility of assembly-disassembly longitudinal and transverse sandwich insulation panels. On the surface of the longitudinal panels is mounted a heating element, made of carbon fiber, placed in an electroinsulating sheath. At one end of the reservoir is fixed a processing platform (13), to which is fixed a central guide (12), mounted along the full length of the grid (11), on the guide (12) is mounted a carriage with a vermicompost extractor with a mechanism of its reciprocating motion and limiting lateral guides (14) mounted along the full length of the grid (11). The vermicompost extractor contains three flaps, rigidly fixed on the carriage, parallel to each other, with some distance between them.

Description

The invention refers to the technology of producing vermiculture and vermicompost by processing vegetable waste from the agro-industrial complex, the food industry, the fish industry, as well as inorganic waste.

It is known that stocks from the pulp and paper industry, sawdust, waste paper serve as raw materials for the production of compost rich in valuable organic substances, microflora and trace elements, which serve for the growth of compost worms of the genus Eisenia, which are from the family of common earthworms (Lumbricidae), the order of higher oligochaetes (Lumbricomorpha), the class of oligochaetes (Oligochaeta), the subtype of ringed worms (Clitellata), the type of annelids (Annelida), from the group of those living on the surface. The following species are used for the production of compost: Eisenia foetida andrei, Eudrillus engenial, Peronyx excavatus. The body of the worms contains almost all amino acids, including biologically valuable amino acids, such as lysine and methionine. The obtained vermiculture has a high albumin content, due to which it can be used as a feed supplement for farm animals (for large horned cattle, pigs), for fish and poultry. Vermiculture biomass is rich in enzymes, vitamins and useful trace elements.

The vermiculture production plant is known, which includes a device for cutting waste, containers for processing them, a processing chamber and a base, on which the material for processing is placed, also on the base there is a material distributor. In addition, the plant is equipped with a harvester for removing the material from the processing chamber and an aggregate for collecting the processed material, which includes a flexible porous belt wound on a drum. Below the base of the processing chamber is located a platform for collecting the processed material, which is transferred by a conveyor to the unloading area. The containers for processing waste are installed one above the other, and the harvester is made with the possibility of moving to the position for collecting the processed material for each container for processing, at the same time the flexible belt for collecting the processed material is made with the possibility of its use by each container for processing [1].

The disadvantages of the known installation consist in the complexity of the construction and the impossibility of using it throughout the year.

Also known is the installation for industrially breeding earthworms, which contains a container, a means of loading and unloading, an irrigation system, heating and lighting means. The container is made in the form of a cylindrical platform, on which inner and outer rings are installed, which form an annular channel equipped with means for lifting the partition wall. In addition, a hollow cylindrical support can be installed in the inner ring, and the means of loading the irrigation system is installed on a support with the possibility of rotation around the vertical axis and on consoles for adjusting the height of the location of the means of loading and unloading [2].

The disadvantages of the mentioned installation consist of limited productivity, complexity of use throughout the year, high energy consumption to maintain vital conditions for earthworms, high workload when servicing the installation for producing vermicompost.

The closest solution is the vermicompost production plant, which includes an actual vermicompost production apparatus, which contains a container for loading the waste to be processed, a waste discharge device, a discharge container for discharging the obtained vermicompost. The discharge container contains a perforated floor, as well as a device for moving the material, produced by vermiculture, in the form of an elongated element for directing the material from the container downwards through the holes in the floor. The device for moving the material is placed parallel to the discharge container of greater length. The device for moving the material represents in plan a triangle with a rectangular cross-section or a dome, which is equipped with one or more vertical teeth. The device or teeth are equipped with a diaphragm and with means for pumping air into the holes of the diaphragm. The material moving device includes a second elongated member, positioned at a right angle to the first elongated member with an upward inclination, such that these members form a simple cross-shaped structure in plan. The length of the second elongated member is not less than two-thirds of the length of the first elongated member. One end of the second elongated member is connected to a winch cable or to the drive sprocket chain [3].

The disadvantages of the installation are that a considerable part of the worms are injured as a result of the penetration of the cross-shaped knife into the depth of the vermiculture layer, there is a possibility of deformation and jamming of the cross-shaped knife during the direction of the material from the container downwards, in case of an uneven density of the material at the edge of the container walls. In addition, the mentioned knife directly scrapes the perforated floor, producing a loud noise, which influences the behavior of the worms, creating a state of stress for them. It should also be mentioned that the installation cannot be used throughout the year, due to the fact that the difference in temperatures of the ambient air and the humid environment of the vermicompost reaches 3…5°C, and the working temperature, necessary for vermiculture, reaches 20…21°C, while the ambient temperature should be 24…25°C.

The problem that the invention solves is the creation of a plant for the production of vermicompost and vermiculture by processing vegetable waste from the agro-industrial complex and other waste, which would operate throughout the year in the conditions of the central area and have increased productivity.

The installation for the production of vermiculture and vermicompost eliminates the above-mentioned disadvantages by consisting of at least one module, which includes a tank for substrate, vermiculture and vermicompost, made as a rigid modular construction, formed by central and lateral vertical uprights, on which lateral frames are fixed, reinforced with the help of connecting bars, and load-bearing angles, on which support frames are fixed, on which a net is placed. To the lateral frames, lateral vertical uprights and load-bearing angles, longitudinal and transverse thermal insulation layered panels are fixed with the possibility of assembly-disassembly. On the surface of the longitudinal panels, a heating element is mounted, made of fibrous carbon material, placed in an electrically insulating cover. A technological platform is fixed at one end of the tank, to which a central guide is fixed, installed along the entire length of the net, on the guide is placed a cart with a vermicompost extractor with a mechanism for its alternative movement, and some lateral limiter guides installed along the entire length of the net.

The vermicompost extractor overcomes the above-mentioned disadvantages by containing three flaps, rigidly fixed on a carriage, parallel to each other, with a certain distance between them. The side flaps are made in cross-section in the form of a partially cut deltoid segment, with elongated surfaces, the upper one convex and the lower one concave, and placed as if in a mirror to each other, between them being placed the central flap, which is made in cross-section in the form of a circle segment with laterally elongated surfaces and placed with the convex surface congruent with the lower concave surfaces of the side flaps. The ratio between the maximum heights, in cross-section, of the central flap and the side flaps is 1:1.1.

The result of the invention consists in ensuring the possibility of using the installation throughout the year due to the installation of longitudinal and transverse thermal insulation layered panels, on the surface of which a heating element is mounted, made of carbon fiber material, placed in an electrically insulating cover, and in increasing the productivity of the installation due to the use of the extractor of complicated geometric shape and the exclusion of its deformation and blocking due to the uneven density of the material produced by vermiculture.

The invention is explained by the drawings in Fig. 1 - 9, which represent:

- Fig. 1, general view of the installation for the production of vermiculture and vermicompost;

- Fig. 2, side view of the installation;

- Fig. 3, top view of the installation;

- Fig. 4, front view of the installation;

- Fig. 5, side view of the extractor as a whole;

- Fig. 6, side view of the central flap of the extractor;

- Fig. 7, side view of the side flap of the extractor;

- Fig. 8, top view of the extractor assembled with trolley;

- Fig. 9, placement of vermiculture and vermicompost layers in the installation.

The vermiculture and vermicompost production plant is a modular construction. The dimensions of the individual module have been selected in such a way as to ensure the processing of organic and inorganic waste in a volume of 1.5 m3 with an effective surface area of 3 m2. Depending on the required productivity of the plant, its surface area can be increased by a factor of 2, i.e. the number of modules varies from 1 to n + 1.

The module is a tank for substrate, vermiculture and vermicompost, consisting of side frames 1 (see Fig. 2), fixed on central and lateral vertical uprights 2, made of pipes with rectangular section, located at the ends of the module and in its middle. The central vertical upright 2 has a non-removable joint with the lateral vertical limiting supports by means of connecting bars 3, made of pipes with rectangular section, installed at an angle of 67° to the horizontal.

In the upper part of the side frame 1, along its entire length, a supporting angle 4 for reinforcing the arched dome is reinforced with a bolted connection, which, in addition to the function of the casing, also serves as a guide for the mechanism for reinforcing the arched dome with two movable layers and for moving the mechanisms for wetting and distributing the fresh substrate (not shown). Along the side frame 1, along its entire length, at a height of 1.9 of the height of the vertical uprights 2 from the lower point, a supporting angle 5 made of steel is placed for reinforcing the longitudinal thermal insulation laminated panels 6, which are also reinforced by the vertical uprights 2 with a bolted connection. Support frames 8 are fixed to the supporting angles 5, on which a mesh 11 is placed.

Longitudinal thermal insulation laminated panels 6 (see Fig. 4) are a demountable construction made of prefabricated elements, consisting of edge sheets (polystyrene sheets or an analogous material with high durability and low water absorption coefficient), between which a thermal insulation layer is arranged (expanded extruded polystyrene or an analogous material with a low thermal conductivity coefficient of not less than 0.032 V/m K). The ratio between the thickness of the inner sheet of the panel 6 and the thermal insulation layer is 1:2. The ratio between the thickness of the outer sheet of the panel 6 and the thermal insulation layer is 10:1.

The sheets of the thermal insulation panel 6 are enclosed in a box, having through holes, which pass through the marginal sheets and the thermal insulation layer and are intended for reinforcing the panel 6 to the inner side of the side frame 1, which is reinforced by means of a screw connection to the supporting angle 5. The transverse thermal insulation laminated panels 7 (see Fig. 1) represent a construction made of prefabricated demountable elements, analogous to the longitudinal thermal insulation laminated panels 6 (see Fig. 2). The ratio between the long side of the transverse thermal insulation laminated panel 7 and the long side of the longitudinal thermal insulation laminated panel 6 is 1.3:1.

The support frame 8 is made of rectangular cross-section pipes and has the shape of a rectangle in plan. The ratio of the length to the width of the support frame 8 is 1:1.3. The support frame 8 is reinforced by means of a bolted connection to the supporting angle 5.

The front transverse thermal insulation laminated panel 9 is intended for servicing the trolley with extractor 10 and ensuring its alternative movement along the mesh 11 on the central guide 12 (see Fig. 3). The front thermal insulation laminated panel 9 is prefabricated and removable, analogous to the longitudinal thermal insulation laminated panels 6 and is tightly reinforced by the transverse thermal insulation laminated panels 7 on the lower part of the side frame 1.

The mesh 11 is reinforced in the center of the support frame 8 with the help of the central guide 12, fixed on the technological platform 13 (see fig. 2, 3, 4), made of a pipe with a rectangular section, to which the supporting angles 5 are rigidly fixed. The length of the central guide 12 is equal to the length of the module.

The technological platform 13 is intended for the installation of the reciprocating movement mechanism, electric or manual, for transmitting the movement to the extractor trolley 10, which moves on the central guide 12, which prevents possible deformations in the horizontal and vertical planes during the movement of the extractor in the layer of processed organic material.

The installation also includes lateral guide-limiters 14, located on the side of the side frames 1, made of material with a high sliding coefficient (fluoroplastic, polypropylene) and intended for eliminating possible deformations in the horizontal plane during the reciprocating movement of the trolley with the extractor 10 in the processed organic fertilizer layer.

The vermicompost extractor 10 represents a construction of complicated geometric shape, consisting of three parts, made in the form of side flaps 15 and 17, and central 16 (see fig. 5 - 8).

The side flaps 15 and 17 of the extractor 10 are made in cross-section in the shape of a partially cut deltoid segment, with elongated surfaces, the upper one convex and the lower one concave, and are placed symmetrically as in a mirror to each other, and the central flap 16 is made in cross-section in the shape of a circle segment with laterally elongated surfaces and is placed with the convex surface congruent with the concave lower surfaces of the side flaps 15 and 17.

The ratio between the maximum heights, in cross-section, of the central flap 16 of the extractor and the side flaps 15 and 17 is 1:1.1.

The side flaps 15 and 17 and the central flap 16 of the extractor are rigidly reinforced by the carriage, which performs the reciprocating movement of the extractor on the central guide 12 within the limits of the vermicompost production installation and also ensures the movement of the extractor on the technological platform 13 for the purpose of prophylaxis or repair.

The extractor of the proposed form makes it possible to efficiently extract and press the finished organic fertilizer through the mesh 11.

The electric winch 18 ensures the reciprocating movement of the extractor within the limits of the installation with an effort from 600 to 1200 N.

The heating element 19 is made of carbon fiber material, placed in an electrically insulating cover made of fiberglass fabric and lined with a layer of silicone material, which allows it to operate in an environment with high humidity and ensures the maintenance of the optimal temperature regime in the vital layer of vermiculture. The heating element 19 is glued to the flat surface of the longitudinal thermal insulation laminated panels 6 using high-temperature resistant silicone glue.

During the operation of the installation, the physiological peculiarities of the biological activity of earthworms must be taken into account.

The order of placing the layers of material to be processed (Fig. 9) in the installation for the production of vermiculture and vermicompost is established on the basis of the cyclical development of earthworms in technological strains. First, paper waste or microcellulose is placed on the mesh 11 - this forms the lower layer, above - a fresh substrate (pre-composted chicken manure, manure, food waste, vegetable waste, etc.), and above is the working area, where the vermiculture is supplied with substrate.

The fresh substrate is prepared within 3…4 weeks. After the fresh substrate is placed, the temperature rises sharply to 55…75°C, then a decrease in temperature is observed and the stabilization phase begins. After the temperature drops, the substrate is placed on top of the paper waste or microcellulose lying on the 11 mesh.

After placement, the base substrate is moistened once a day for four days. At the same time, the calcium carbonate is dissolved and the excessive acidity is neutralized, and the substrate is saturated with oxygen.

The vermiculture is placed on the substrate. The thickness of the area where the vermiculture feeds on the substrate is approximately 5 cm, below is the relaxation area for the earthworms, 10 cm thick. The total thickness of the working area where the vermiculture lives is 10…15 cm.

The primary population is 30…50 thousand individuals per 2 m2 area. During the year, when optimal conditions are maintained, earthworms go through 2 reproduction cycles and their number increases more than 1000 times. In addition, it has been established that earthworms emerge from cocoons in 1…2 weeks and in 3…4 months reach the size of a mature earthworm. Organic raw material, populated by earthworms within 1…2 days, loses its unpleasant odor, and in 4…6 weeks turns into high-quality organic fertilizer - vermicompost, which improves the physicochemical properties of the soil, prevents the leaching of nutrients from it, reduces the action of harmful salts and phytotoxic elements, radionuclides and heavy metals, increases the yield of agricultural crops. The presence of humic acids in it increases the ecological plasticity of plants, resistance to adverse conditions, resistance to diseases, stimulates production processes, and improves the quality of production.

The obtained vermiculture is a very valuable albuminous product - earthworm biomass. Their dry matter contains up to 60% of good quality albumin with a high level of irreplaceable amino acids, 20...25% of liquid fat with a high iodine content, a wide range of microelements and vitamins. Earthworm meal is not inferior to meat and bone meal and fish meal in its nutritional value.

Earthworm biomass can be used as a feed supplement for farm animals (for large horned cattle, pigs), for fish and birds.

After 10...15 days, the surface must be covered with a new portion of substrate with a thickness of 5...6 cm.

The complicated geometric shape of the extractor 10 makes it possible to smoothly lift the organic fertilizer above the mesh 11, which prevents the processed material from splashing during the reciprocating movement of the extractor trolley 10 on the central guide 12 along the mesh 11 of the installation for the production of vermiculture and vermicompost. The vermicompost, during the movement of the extractor 10, is lifted by the side flap 15 of the extractor 10 and a part of the vermicompost is detached and falls into the channel formed by the elongated concave (lower) surface of the side flap 15 and the convex surface of the central flap 16 of the extractor 10. The side flap 17 of the extractor 10 cuts the material, which comes quickly towards it, and directs the cut layer into the channel formed by the elongated concave surface of the side flap 17 and the convex surface of the central flap 16 of the extractor 10. The same thing happens during the movement of the extractor 10 in the opposite direction.

For the transformation of the substrate into vermicompost and the multiple regeneration of the worms in the installation, optimal conditions for the vital activity of the worms are maintained, i.e. for their feeding, maintenance of the optimal temperature. Maintaining the optimal temperature with the help of heating elements 19, made of fibrous carbon material, enables the installation to operate in an environment with increased humidity and ensures the maintenance of the optimal temperature regime in the vital layer.

Thus, the proposed technical solution makes it possible to maintain the necessary thermal and humidity regime in the installation, to ensure the production of vermicompost and vermiculture throughout the year and to increase productivity based on the considerable increase in the share of unharmed earthworms by eliminating the deformation and blocking of the extractor, by attenuating the noise during the movement of the extractor and the material and by ensuring the possibility of lifting it above the net 11.

1. US 7422894 B2 2008.09.09

2. SU 1790359 A3 1993.01.23

3. US 2002144658 A1 2002.10.10

Claims (2)

1. Installation for the production of vermiculture and vermicompost, which consists of at least one module, which includes a tank for substrate, vermiculture and vermicompost, made as a rigid modular construction, formed by central and lateral vertical uprights (2), on which lateral frames (1) are fixed, reinforced by means of connecting bars (3), and load-bearing angles (5), on which support frames (8) are fixed, on which a net (11) is placed; longitudinal (6) and transverse (7) thermally insulating laminated panels are fixed to the lateral frames (1), the lateral vertical uprights (2) and the load-bearing angles (5) with the possibility of assembly-disassembly; on the surface of the longitudinal panels (6) is mounted a heating element (19), made of fibrous carbon material, placed in an electrically insulating cover; A technological platform (13) is fixed at one end of the tank, to which a central guide (12) is fixed, installed along the entire length of the net (11), on the guide (12) a trolley with a vermicompost extractor (10) with a mechanism for its reciprocating movement is placed, and some lateral limiter guides (14) installed along the entire length of the net (11). 2. Vermicompost extractor (10), comprising three flaps (15, 16, 17), rigidly fixed on a carriage, parallel to each other, with a certain distance between them; the lateral flaps (15, 17) are made in cross-section in the shape of a deltoid segment, partially cut, with elongated surfaces, the upper one convex and the lower one concave, and placed as if in a mirror with respect to each other, between them being placed the central flap (16), which is made in cross-section in the shape of a circle segment with laterally elongated surfaces and placed with the convex surface congruent with the concave lower surfaces of the lateral flaps (15, 17), the ratio between the maximum heights, in cross-section, of the central flap (16) and the lateral flaps (15, 17) being 1:1.1.