RU2088079C1 - Method for cultivation of synanthropic fly larvae - Google Patents

Abstract

FIELD: agriculture, in particular, biological reprocessing of animal wastes. SUBSTANCE: method involves providing perforated receptacle penetratable by larvae, with thickness of manure layer placed within receptacle being equal to depth of penetration of larvae into substrate; arranging receptacle in horizontal position during growing period and supplying air flow along receptacle wall; moving perforated receptacle to vertical position, when larvae are to be separated from substrate, and stopping supplying of air flow. EFFECT: increased efficiency and simplified method. 2 cl, 2 dwg, 1 tbl

Description

 The present invention relates to the field of agriculture, in particular to the processing of animal waste by the biological method.

 A known method of processing manure by larvae of synanthropic flies, implemented in the installation for processing manure by invertebrate animals saprophages (ed. St. USSR N 966948, class A 01 K 67/00). Larvae are cultivated in horizontally located trays installed in containers with an adjustable microclimate. Rectangular trays have a continuous bottom and sides, the height of the sides is 3 times the height of the layer of manure processed in them to complicate the migration of larvae, which significantly reduces the utilization rate of the internal volume of the installation. The depth of manure processing does not exceed 5–8 cm, and its moisture content should not exceed 81%; otherwise, eggs and hatching larvae of synanthropic flies will drown in such manure. At an optimum substrate moisture content of 78%, up to 75% of larvae die in it during processing. With increasing humidity of the substrate, the percentage of larvae death in the substrate increases, which leads to a sharp decrease in the biomass yield of larvae and a decrease in the quality of processing of the substrate.

 A known method of producing larvae of synanthropic flies (RF patent N 1491427, class A 01 K 67/00), in which the cultivation of larvae is carried out in vertically arranged perforated containers, permeable to the liquid fraction of manure and larvae of synanthropic flies. During the development of the larvae, starting from the third day, an air flow is supplied along the walls of the containers, and during the collection of the larvae, on the fifth or sixth day after the eggs are introduced into the manure, the air flow is stopped and the enclosure is partially sealed. The eggs of the flies are brought onto the surface of the manure in the upper part of the perforated container.

 Currently, this method is the most effective way of processing animal waste. However, he has the following disadvantages. The research results showed that a high yield of larval biomass is ensured by a high percentage of their survival, rather than an increase in the body weight of each larva. The optimal hydrothermal and nutritional conditions for hatching eggs and the development of larvae of synanthropic flies are created only in the initial period of development of the larvae, that is, during the first 2-3 days, and then the supply of larvae with nutrients deteriorates due to the uneven distribution of larvae in the volume of the substrate. This is a consequence of the fact that in the first two days the larvae very slowly gain body weight, are small in size and have enough food at the place of introduction. Thus, there are no factors inducing larvae to actively migrate from the place of introduction, and their small size also does not facilitate migration over long distances from the place of introduction. However, on the third day there is a multiple, almost spasmodic increase in the body weight of the larvae, which forces them to migrate in search of an unprocessed substrate. It would seem easier for larvae to move along the perforated walls of the tank, but the large mass and slippery surface of the body of the larvae do not allow them to stay on the side perforated walls of the tank and some of them can crumble, which will lead to loss of biomass. Therefore, in the prototype method, on the third day, air is blown around the perforated walls of the container so that the larvae leave the surface in the thickness of the substrate. Thus, the larvae are unable to migrate to the lower part of the perforated container along the side walls of the container. The movement of larvae in the substrate is as follows. Larvae located in the upper part of the tank, moving to the lower part of the tank in search of unprocessed substrate, fall into the zone of the substrate processed by larvae that had previously migrated along the side walls of the tank. In the processed substrate, the speed of movement of the larvae is much greater than in the unprocessed. Thus, on about the third and fourth day, most of the larvae concentrate on the border of the processed and unprocessed substrate into one large group, which leads to a sharp decrease in the substrate processing front. Access to the unprocessed substrate is obtained only by the larvae located in the head of this group, and the larvae located in the center and in the tail of this group are forced to feed on stools of anterior larvae, which leads to insufficient weight gain of all larvae, since the larvae in the group change places, they push each other out in the struggle for access to feed. The constant expenditure of efforts on penetration to an unprocessed substrate adversely affects the rate of increase in body weight of the larvae.

 The present invention solves the problem of increasing the biomass yield of larvae by increasing the body weight of each larva by creating optimal conditions for their growth and development. Increasing the biomass yield of larvae by increasing the percentage of their survival by creating conditions that reduce the death of eggs and larvae in a liquid substrate. According to the proposed method for producing larvae of synanthropic flies, the cultivation of larvae is carried out in a tank permeable to liquid, air and larvae of synanthropic flies, with a thickness of the layer of manure in the tank equal to the depth of penetration of the larvae into the substrate. Moreover, the introduction of eggs and the cultivation of larvae is carried out with a horizontal arrangement of perforated containers. Loading containers with a substrate can be carried out in vertical and horizontal positions. For example, after loading the containers with the substrate, they are brought into a horizontal position, and eggs of synanthropic flies are placed on the surface of the upper perforated wall of the container. After hatching of the larvae and their distribution over the surface of the substrate, the air flow along the walls of the containers is carried out during the entire period of growing the larvae, under the influence of which the possibility of migration of the larvae outside the perforated container is excluded. After the period of development of the larvae, they are separated from the substrate, for which they stop blowing the tank with air flow, put it in a vertical position and partially seal the case.

 The authors found that larvae hatching from eggs are distributed over the surface of the substrate and are introduced into it by separate groups. In each group there is such a number of larvae, in which each larva, if necessary, has free access to the unprocessed substrate, which ensures a uniform and maximum possible increase in body weight of all larvae in the group. As a rule, groups of larvae do not contact each other and process the substrate independently. As the substrate is processed by larvae and their size and body weight increase, especially on the third day, the larvae in the group become cramped as they move to the feed. Some of the larvae that have access to the unprocessed substrate remain in place, while the rest have the opportunity to go to the surface of the substrate (rather than moving in the processed manure) and migrate along the surface of the substrate in search of food (unprocessed substrate). The division of one group of larvae into several small ones can occur continuously as the size of the larvae increases. The blowing of the perforated container, introduced on the third day, prevents the larvae from entering the vertical side walls of the perforated container and the bottom, and the air movement above the upper horizontal surface of the substrate from the blowing of the perforated container does not significantly affect the larvae and does not impede their movement on the substrate surface in search of food .

 The inventive method allows, in comparison with the prototype, to provide equally and in a sufficient amount of all hatching larvae with substrate nutrients and thereby increase the biomass yield of larvae by 50 percent or more, increase the survival rate of larvae to 70 percent or more. The inventive method provides a biomass yield of larvae higher than the biomass yield when eggs are placed in a vertically arranged perforated container with their distribution (eggs) along the height of the tank (ed. St. CCCP N 1676566, class A 01 K 67/00).

 In addition, the device for introducing eggs into the substrate has a rather complex and cumbersome design and is difficult to operate.

 The inventive method differs from the prototype in that the cultivation of synanthropic flies is carried out with a horizontal arrangement of a perforated container.

 The authors are aware of growing larvae of synanthropic flies in an installation (ed. St. USSR N 873919, class A 01 C 3/00) containing a tray in the bottom of which tubes with capillary holes are mounted, the tubes being connected in series with a fan, heater and air dispenser. Formally, a tray with a bottom having tubes with capillary holes could be attributed to a container with a perforated bottom. But capillary holes are not intended to exit the excess liquid fraction from the substrate and to create normal conditions for the development of larvae in this way. Air is pumped through the capillaries into the substrate, which is not evenly distributed in the substrate, since the substrate has an inhomogeneous structure and has a different resistance in all its zones to the air injected into it. The latter goes out through the zones of least resistance, forming gaps in the substrate and dragging the liquid contained in it onto its own surface, which spills over the said surface and fills the passages made by the larvae and isolates the larvae from the air, thereby causing their death. Moreover, the higher the humidity of the substrate, the more sunken larvae.

 In addition, the horizontal arrangement of the capacities of the trays in the described and other installations is accepted only to create a substrate layer with a thickness corresponding to the depth of penetration of the larvae into the substrate. In installations of this type, it is 5 8 cm.

 From the presented information and other sources known to the authors, the idea of the need to place a perforated container with a substrate horizontally during the growing of larvae does not follow in an obvious way.

 In FIG. 1 and 2 are a schematic diagram of one embodiment of a device for implementing the inventive method, manufactured and tested at the Novosibirsk State Agrarian University.

 The device comprises a housing 1, inside which a perforated container 2 is located. The space between the housing 1 and the perforated container 2 forms ventilation corridors 3. The upper part of the housing 1 is closed by a continuous cover 4, and the upper part of the container 2 by a perforated cover 5. On one of the sides of the housing 1 a window 6 is located, closed by a cover 7. The housing 1 is located on the frame 8 by means of the axes 9, with the possibility of changing the position in space. To fix the housing 1 and, respectively, of the container 2, both in the vertical and horizontal position, a latch 10 is installed on the bed 8. In the lower part of the housing 1, under the perforated container 2, there is a receiving device for the liquid fraction, larvae and biofuel, made in the form of a container 11. To create an air flow blowing around the walls of the perforated container 2, the housing 1 is communicated by means of an air duct 12 with a fan 13.

 The device operates as follows. Using a loading device (not shown in FIG.), Load the perforated container 2 with the substrate and close it with the perforated cover 5. When the perforated container 2 is horizontally placed, eggs of synanthropic flies are brought into the upper perforated wall through the window 6. Placing eggs on the surface of the substrate, covered by perforation, prevents the death of eggs and hatching larvae of synanthropic flies even if the humidity of the substrate exceeds 90%. After the introduction of the eggs, the window 6 is closed with a cover 7. As a result of evaporation of the moisture of the substrate inside the housing 1, the air humidity reaches 100% which is the optimal condition for hatching of larvae and their safety. Moreover, the percentage of hatching can reach 90–99% since the eggs of the flies were introduced onto the horizontal perforated wall of the tank 2, and if by the time of hatching the larvae the substrate in its upper part does not have time to reduce its moisture to 70–75% moisture, at which the larvae of synanthropic flies practically do not die in substrate, the hatching larvae will use the upper perforated wall of tank 2 as a substrate, and the liquid substrate in contact with perforation as a feed. As the moisture content of the top layer of processed animal waste is reduced to a level safe for the larvae, the larvae will migrate from the perforated wall of tank 2 to the processed animal waste and use it not only as feed, but also as a substrate, which will increase the survival rate of larvae to 70% and more. On the third day after the introduction of eggs, a fan 13 blows the perforated container 2 with air, which excludes the possibility of migration of the larvae outside the perforated container 2. Since the processing of the substrate by the larvae of synanthropic flies, as well as the drain of excess liquid fraction of the substrate, is accompanied by a decrease in its volume, then the distance between the upper wall of the perforated container 2 and the surface of the substrate gradually increases, which in turn slows down the speed of the air flow above the upper surface of the substrate by increasing the clearance of the ventilation corridor 3. In addition, the perforation located above the surface of the substrate drastically slows down the speed of air movement above the upper surface of the substrate to a point where the larvae do not respond to it and, if necessary, they can migrate along its surface to unprocessed sections of the substrate. On the sixth day, the processing process ends. To separate the larvae from the substrate, the perforated container 2 is blown off, the housing 1 is moved to a vertical position, fixed with a latch 10 and the housing 1 is closed with a cover 4. Under the influence of a number of factors, oxygen deficiency for respiration, increased substrate temperature and high mobility of the larvae in the pre-pupal phase, the larvae emerge on the surface of the perforated walls and poured from them into the receiving device, made in the form of a container 11. After separating the larvae, the perforated container 2 is turned upside down, the covers 4 and 5 are opened yvayut then BioPeregnoy poured into the container 11.

 Currently, a production line for the processing of manure by larvae of synanthropic flies has been built and is being operated in the bio-workshop of the Novosibirsk State Agrarian University (Aut. St. USSR N 1827761). The installation is a closed multi-tier chain conveyor that moves the trays with the substrate, with one side of the trays connected to the chain, and the opposite by means of rollers resting on a support beam, which ensures that the trays sway from side to side during movement.

 The installation has the following disadvantages. The chain conveyor and its servicing mechanisms occupy up to half the installation volume. When the tray is tilted, the liquid substrate flows down to the tilt side and overflows over the edge of the tray, together with hatching larvae, which leads to a decrease in the biomass yield of the larvae and a deterioration in the quality of processing the substrate.

It is known that during the period of processing the substrate by larvae of synanthropic flies in horizontal trays with continuous walls and the bottom, the height of the substrate decreases by 25 30%. The presence of a perforated bottom allows you to increase the height of the processed layer of the substrate by another 25 30%
Example. The depth of penetration of larvae into the substrate in a horizontal tray with a solid bottom is not more than 8 cm. In a vertical perforated container 16 cm due to the fact that air penetrates into the substrate from two sides. However, to a depth of 8 cm, 100% of the air necessary for the larvae to breathe penetrates, and to a depth of 8 to 12 cm, that is, only 50% of the air of the amount necessary for the larvae to breathe penetrates into the 4-centimeter zone. If the height of the substrate is chosen so that 50% of the oxygen necessary for breathing larvae penetrate into the aforementioned four-centimeter zone, both on one side of the perforated container and on the other side of the container, then in total 100% of atmospheric oxygen will enter this zone . Thus, the depth of penetration of the larvae into the substrate or the height of the processed layer of the substrate will be 8 cm + 4 cm + 8 cm 20 cm, which is confirmed experimentally. The horizontal location of the perforated container will increase the height of the processed layer by another 25 30% or 6 cm. Therefore, in the proposed method, the total height of the processed layer will be 26 cm.

 Thus, in a horizontal perforated container, a wide front of substrate processing and the possibility of free divergence with each other of individual groups of larvae are provided. The volume of processing of raw materials increases by 25–30%. The introduction of synanthropic flies eggs on the perforated wall of the tank significantly increases the survival rate of larvae and, accordingly, the biomass yield of larvae.

 The effectiveness of the proposed method is confirmed by calculated and experimental data.

 So, for example, when growing larvae in a vertical perforated container, the yield of larvae biomass was 50 kg / t, the mass of 1 larva was 20 mg, and the survival rate was 42% (see table).

 In the proposed method under the same temperature and humidity conditions, the biomass yield was 97 kg / t, the mass of 1 larva 24 mg, the survival rate of 70%

Claims (2)

 1. A method of producing larvae of synanthropic flies, including cultivating larvae on manure in a perforated and permeable tank for larvae with a thickness of the layer of manure in it equal to the depth of penetration of the larvae in the manure, with air flow along the walls of the tank during the development of the larvae and the cessation of air flow along the walls of the perforated container during the period of separation of the larvae from the substrate, carried out with the vertical arrangement of the perforated container, characterized in that the larvae are grown at horizontal arrangement of a perforated and permeable container for larvae.  2. The method according to claim 1, characterized in that the eggs of the larvae of synanthropic flies or hatching from the eggs of the larvae are placed on the upper surface of the perforated container.

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