RU2101267C1 - Method and installation for producing humus - Google Patents

Abstract

FIELD: organic fertilizers. SUBSTANCE: invention relates to processing industrial, agricultural, and other wastes using California worms. Preliminarily prepared substrate is populated by mother worm culture with specified density and composted at specified temperature, humidity of substrate, and aeration degree. Process is conducted in sections mounted on a rotary shaft for 10-14 days, after which sections are complemented with fresh substrate and composting is continued for further 10-14 days. All amount of vermicompost obtained in section conditionally defined as the first section is then distributed among a part of sections consecutively located after the first one, while simultaneously replenishing remaining sections and completely filling the first section with fresh portions of substrate, the operation being continued in similar manner with all sections up to the last one. When the last section undergoes redistribution and replenishment procedures, vermicompost in the next to the last section is loosened up to the bottom and migration passages between sections are purged. Composting is carried out for 5-7 more days and vermicompost from the next to the last section is discharged onto screen bottom of admission tray. Installation comprises enclosure protecting process containers for substrate constructed as sections of drum mounted on rotary shaft with air channel and migration passages analogous to those in intersectional divisions. Installation is provided with admission tray, heat and moisture controlling systems, apron, drip pan, and splitters inside sections. EFFECT: enhanced efficiency of composting process. 4 cl, 2 dwg

Description

 The invention relates to agriculture, namely to the production of organic fertilizers based on waste processing industry, agriculture, meat processing industry Vermi-culture.

As an analogue of the proposed method for the production of vermicompost, you can bring the method, which consists in preparing the substrate, introducing the uterine culture of the worms into it, laying the substrate in piles and composting, and then separating the obtained vermicompost from the worms, drying, grinding and sifting, and composting carried out at a density of worms of 1.5-2 thousand per 1 m ² for 20-30 days at a humidity of 60-80 and aeration (see ed. St. N 1724658, class C 05 F 11/00, 1992).

 The known technology does not provide biohumus with a high trace element content; when producing biohumus in piles, it is impossible to maintain temperature and humidity with the necessary degree of accuracy, which significantly affect the growth of the worm population, the processing speed of the substrate, and the quality of biohumus. Known technology does not allow to obtain a liquid fertilizer concentrate.

As a prototype, a method for producing biohumus can be cited, in which the substrate is first prepared, the collars are formed, they are populated with the uterine culture of worms with a density of 25-30 thousand individuals per 1 m ² , the collars are covered with a film, then, with the help of irrigation, the substrate humidity is 80-87 the degree of aeration is 45-50 with an interval of 3-5 days, they are watered, the first 3-4 weeks are not top-fed, if necessary, loosening is carried out, after 3-4 weeks the first top-dressing is carried out, and the following are carried out after 8-10 days for 2-2 , 5 months, then Vermiculture is separated [1]
However, the technology of producing vermicompost in the piles does not provide fertilizer with a high content of trace elements, it is impossible to maintain stable technological parameters of temperature, humidity, provide sufficient aeration, ensure good life activity, vitality and safety of worms, and obtain a liquid fertilizer concentrate. The entire cycle of obtaining vermicompost is very long.

 To implement the most common methods of producing vermicompost, widely known technical means are used, such as tractors and bulldozers, to form collars, which, like frequently used boxes or other containers, are filled with a substrate with a worm population placed in it, and irrigation machines are used for irrigation or hoses, and loosening is carried out using a shovel or pitchfork. Such technical means can be considered as an analogue of the proposed device, but they are inefficient, time-consuming, do not allow to mechanize the technological process, accelerate it and do not allow to achieve good results on the growth of worms, increase their population, do not ensure their safety (see. "Chemistry in rural economy ", N 1, 1995, p. 17-18).

Closest to the proposed technical solution is a plant for the production of vermicompost containing a fence, in the volume of which are technological tanks arranged in accordance with the technological process with the organization of the place of loading of the substrate and the place of unloading of vermicompost equipped with a receiving tray, as well as moisture and temperature control systems [2]
The disadvantages of the known technical solutions include the low productivity of the installation, the technological process carried out on it does not provide biohumus with a high content of trace elements and liquid fertilizer concentrate.

 The technical problem to which the invention is directed is to obtain biohumus with a high content of trace elements, increase plant productivity, provide the possibility of obtaining a liquid fertilizer concentrate, as well as create conditions for the rapid growth of worms, increase their population at all stages of the technological process.

To solve this problem, a method is proposed, which consists in a certain sequence and cyclical operations. The method consists in first preparing the substrate, populating it with the uterine culture of worms with a density of 25-30 thousand individuals per 1 m ² and at a temperature of 20-25 ^o C, substrate humidity 80-87 and degree of aeration 45-50 compost, and to the proposed method, the substrate is laid in sections mounted on a rotating axis, the uterine population of worms is introduced into them and composted for 10-14 days, then all sections are refilled with fresh substrate, and after 10-14 days the contents of the section, which is conditionally first, are redistributed into part of the sections , P consequently located behind it, while the remaining sections are refueling, and the first is refilled with a fresh substrate, and so on, all sections to the last, and at the same time redistributing the contents of the last section and filling it with fresh substrate, vermicompost in the next section (with the finished product) carefully, to the bottom loosen, clean the migration passages between these two sections and compost for another 5-7 days, after which they turn the drum into the unloading position and the vermicompost from the ready section is unloaded onto the net bottom output tray, a sieve bottom which is fresh substrate and vermicompost is left in the output tray for 3-4 days, and the operation with the redistribution of content sections and refueling them is carried out in the same scheme, but after 7-9 days.

Salient features of the proposed method from the known are the following:
sections mounted on a rotating axis are filled with the prepared substrate, and the uterine population of worms is introduced into it;
after composting for 10-14 days, the sections are refilled with fresh substrate;
after subsequent composting for 10-14 days, the contents of the conditionally first section are redistributed into part of the sections sequentially located behind it;
the remaining sections are refueled, and the first is filled with fresh substrate;
after composting for 10-14 days, redistribute the contents of the next section and so on until the last;
simultaneously with the redistribution of the contents of the last section and filling it with a fresh substrate, the vermicompost in the next section with the finished product is thoroughly loosened to the bottom, the migration passages between these sections are cleaned and composted for another 5-7 days;
then vermicompost from the first section with the finished product is unloaded on the mesh bottom of the receiving tray, under which there is a fresh substrate.

 To implement the developed technology and achieve the goal, a device is proposed that includes a fence, in the volume of which technological containers are located for placing the substrate with worms placed in it, and the containers according to the technological process are arranged to organize the place of loading of the substrate and the place of unloading of the finished product, which is equipped with a receiving tray, inside the enclosure are also placed thermal and moisture control systems, and in the proposed device flaxen in the form of drum sections mounted on a rotating axis, along which the air channel and migration passages, which are also in intersectional partitions, are made, in addition, dividers are located inside the sections. The device is equipped with an apron and a tray for collecting liquid concentrate, and the receiving tray has a mesh bottom.

Salient features of the proposed device from the prototype are the following:
technological tanks are made in the form of drum sections mounted on a rotating axis;
an air channel and migration passages are made along the axis;
migration passages are also available in intersectional partitions;
dividers are located inside sections;
the device is equipped with an apron and a tray for collecting liquid concentrate;
the receiving tray has a mesh bottom.

 In FIG. 1 shows a plant for the production of biohumus, a side view in section; in FIG. 2, section AA in FIG. one.

 The device for the production of biohumus contains a fence 1, in which sections 3 forming a drum are mounted on a rotating axis 2. Sections 3 are equipped with dividers 4, along the outer contour of section 3 they are closed with fixed covers 5. An air channel 6 is made along the rotating axis 2. The inner drum forming the bottom of 7 sections 3, the intersection partitions 8 have migration passages 9. The rotating axis 2 is mounted on supports 10, which are equipped with position locks 11. An apron 12 and a tray 13 for collecting liquid concentrate are fixed in the lower part, and a heater 14 is located, connected by moisture and temperature control systems 15. Receiving trays 16, located in places Booting vermicompost, provided with a mesh bottom 17. The substrate loading place designated by reference numeral 18.

 The proposed method for the production of vermicompost is as follows.

In a specific case, the content of the pancreas of ruminants (canyang) is used as a feedstock. In order to accelerate the fermentation process, unicellular fungi of the yeast type are populated into the substrate, which contribute to the breakdown of cellulose-containing fractions. The substrate prepared in this way is filled in all sections 3, saturated with the estimated amount of the uterine livestock of worms. Section 3 is closed with fixed covers 5 and composted for 10-14 days. At the same time, in the enclosure 1, with the help of sensors (not shown), moisture and temperature control systems 15 are activated, which automatically maintain the temperature of 20-25 ^o C and humidity 80-87 with the necessary accuracy. When the temperature drops below the permissible limits, the heater 14 made in the form of an open moisture evaporation system located under the drum. Warm vapors, rising upward, equalize the temperature and humidity in each section due to the rotating axis 2, on which sections 3 are mounted. The process is very fast. If the temperature exceeds the permissible limits, sections 3 are irrigated with water, the excess of which flows through the migration passages 9 and the air channel 6 into the apron 12, and then into the tray 13.

 After 10-14 days, all sections 3 are refilled with fresh substrate and composted for another 10-14 days in the same mode. After that, the vermicompost contained in the conditionally first section is redistributed into sections following the first, the remaining sections are refilled, and the first is completely filled with fresh substrate, then again composted for 10-14 days and then redistributed the vermicompost contained in the second section, and so until the last section, and simultaneously with the redistribution of the vermicospost contained in the last section and filling it with a fresh substrate, the vermicospost contained in the section preceding the last one, in which the finished product itself is used, carefully, loosening, clearing (clearing) the migration passages 9 in intersectional partitions 8 between the last section and the section preceding it, and again composting it for 5-7 days, for which the worms go into a fresh substrate . Now the drum is rotated to the unloading position, fixed with clamps 11, while the section with the finished product is above the receiving tray 16. The vermicompost is unloaded on the mesh bottom 17, under which there is a fresh substrate and left here for 3-4 days, during which the worms remaining in the vermicompost go into a fresh substrate, thereby vermicompost is cleaned of the worms and at the same time this technology contributes to the best conservation of the number of worms without injuring them.

Further, all operations with redistribution and refueling are carried out according to the previous scheme, however, they are carried out after 7-9 days, which contributes to:
rapid growth of an individual worm;
a rapid increase in the number of worms;
a change in the density of the worm population, i.e. the ratio of the mass of individuals of worms and the mass of the loaded substrate, when they are equal in mass or exceed the mass of the substrate;
free movement of individuals of worms inside the drum volume due to the presence of migration moves 9 in intersectional partitions 8, in the bottom of 7 sections due to the presence of an air channel 6;
providing optimal living conditions for worms in temperature, humidity and aeration.

 A sufficient degree of aeration is achieved by the design features of the proposed device, namely, the presence of an air channel 6, the presence of migration passages 9 and the creation of air channels inside sections 3 by dividers 4 located in them, which, when the drum rotates, contribute to the formation of free zones of voids, which in turn contributes to the free penetration deep into vermicompost of air, water and the movement of individuals of worms.

 The design features of the device having the drum position locks provide ease of service for all operations, and the rotation of the drum can be carried out in the forward and reverse directions.

 The presence of the fence 1 and automatic temperature and humidity control systems allows you to maintain optimal conditions and achieve significant heat energy savings, and the saving mode can be further increased by heating the volume inside the fence 1 with the sections' own heat, when in one of them the temperature rises significantly, the drum is rotated so that this section is at the bottom and its convection heat will spread throughout the volume.

 The proposed method and device allows to obtain high-quality vermicompost, to implement the technology of growing vermiculture and, in addition, to obtain a liquid fertilizer concentrate with a high content of active trace elements. The collection of liquid concentrate is carried out using an apron 12 in the pallet 13. Features of the technology for producing liquid concentrate and its composition are subject to self-protection.

Claims (4)

1. The method of producing vermicompost, which consists in first preparing the substrate, populating it with the uterine culture of worms with a density of 25 30 thousand individuals per 1 m ² and at 20 28 ^o С, substrate humidity 80 87% and degree of aeration 45 50% characterized in that the substrate is composted in sections mounted on a rotating axis for 10 to 14 days, then all sections are refilled with fresh substrate and again composted for 10 to 14 days, after which the vermicompost contained in the conditionally first section is redistributed into part of the sections located sequentially behind it, while the remaining sections are refueling, and the first is completely filled with fresh substrate, and so on, all sections to the last, at the same time as redistributing the vermicompost contained in the last section and refueling it with fresh substrate, vermicompost in the section preceding the last, carefully loosen to the bottom, clean the migration passages between these sections, compost another 5 7 days, after which the vermicompost of the previous section is unloaded onto the mesh bottom of the receiving tray, and ation with redistribution vermicompost sections and their refueling carried out by the previous scheme, but after 7 9 days.  2. A device for producing vermicompost containing a fence, in the volume of which there are technological containers for placing a substrate with a worm stock placed in it and arranged according to the technological process with the organization of the substrate loading place and the biohumus unloading place, which is equipped with a receiving tray, as well as a thermal and moisture control systems, characterized in that the technological tanks are made in the form of drum sections mounted on a rotating axis, moreover, an air channel and migration passages, which are also in intersectional partitions, in addition, dividers are located inside the sections.  3. The device according to claim 2, characterized in that it is equipped with an apron and a tray for collecting liquid concentrate.  4. The device according to claim 2, characterized in that the receiving tray has a mesh bottom.

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