RU2679036C1 - Nesting box for earthworms by devyatkin - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: proposed artificial nesting device for earthworms. Device includes an underground pipeline, a grid with cells above it, laid on the soil in the upper layers of the beds covered with lid boxes. Holes are made in the bottom of the boxes, and the rods inputting the soil are installed at the bottom. At the bottom of the pipeline there are holes, at one end of the pipeline a suction branch is installed, and an exhaust pipe is installed at the other end. Exhaust pipe and the suction branch include a heating chamber, the heating chambers on the south side have a light-penetrating wall, inside the light-absorbing surface, and outside have a heat-insulating coating.

EFFECT: invention provides air heating of the habitats of worms in the ground, protection of worms from moles, mice and birds.

4 cl, 8 dwg

Description

The invention relates to agriculture, in particular to a device for producing organic fertilizers using a worm culture and is intended for gardening and horticulture.

A device is known, described in patent RU 2033049 C1, consisting of shelving racks, clutches, boxes with a substrate and boxes sieves.

Its disadvantage is the complexity of the device.

A device is known as described in patent RU 2028787 C1, consisting of a conveyor system, rail tracks with arrows and containers.

The disadvantage of this device is the difficulty of its use in a garden plot or garden.

As a prototype taken the device described in patent RU 102291 U1, consisting of boxes with a substrate buried in the ground, irrigation devices and feeders.

Its disadvantage is the complexity of the device.

No devices have been identified to create comfortable and safe conditions for the life of earthworms.

The objective of the invention is to create a design that allows for small farms to create favorable conditions for the life of worms together in symbiosis with cultivated plants.

The technical result of the invention is a new property of the device, namely: the possibility of air heating of the habitats of the worms in the ground, the protection of worms from moles, mice and birds

Achieving the claimed technical result and, as a result, solving the problem is achieved by the fact that birdhouse (artificial nesting) for worms contains a system of protection against earth-moving predators and birds, as well as a system of solar solar heating with dry, moist, warm, hot, aerosol air or their combination and temperature control system.

In FIG. 1 - shows a diagram of air solar heating in open ground; in FIG. 2 - shows the layout of the pipeline, section AA in FIG. one; in FIG. 3 - shows a diagram of the heating chamber on the suction pipe, section BB in FIG. one; in FIG. 4 - shows the layout of the exhaust pipe and exhaust heating chamber section BB in FIG. one; in FIG. 5 - shows a diagram of the shelter of worms from earth-moving predators and birds, section GG in FIG. one; in FIG. 6 shows a diagram of air humidification and aerosol generation; in FIG. 7 - shows a diagram of solar air heating in closed ground; in FIG. 8 - shows a diagram of the supply of hot air to the beds from a solar energy concentrator.

The device consists of an underground pipeline 1, in the lower part of which holes 2 are made, at the southern end of the pipeline 1 there is a suction pipe 3 with holes 4 at its upper end, and an exhaust pipe 5 is installed on the north side (Fig. 1). The suction pipe 3 is closed from above by a heating chamber 6, inside of which are heat accumulators 7 (Figs. 1, 3). The exhaust pipe 5 also has a heating chamber 8, which is connected by the upper part to the internal cavity of the pipe 5 by means of a pipe 9, which enters the exhaust pipe 5 at an angle (Figs. 1, 4). The heating chambers 6 and 8 on the south side have a light-penetrating wall 10, inside a light-absorbing surface 11, and on the outside they have a heat-insulating coating 12. The exhaust pipe 5 is additionally equipped with a deflector 13 (Fig. 1). Inside the heating chamber 6, there is an evaporation bath 23 and a wick 24 (a liquid feed cotton tape immersed in the evaporation bath 23 at one end). The evaporation bath 23 is connected through a pipe 25 to a filling tank 26 located outside the heating chamber 6 (Fig. 6).

To protect the worms located in the depth of the bed 14 from moles, a mesh 15 with cells less than half the diameter of the wormholes is installed above the underground pipeline 1. To protect the worms from mice in the upper layers of the beds 14, boxes 17 closed with a cover 16 are laid on the soil, holes 18 are made in the bottom, and rods 19 included in the soil are installed in the form of a brush from the bottom.

Temperature control is carried out using sensors 27 installed in the heating chamber 6, in the exhaust pipe 5 and in the garden 14.

The solar energy concentrator consists of a sphere-shaped reflective surface 31 and a light-penetrating wall 10 mounted on the suction pipe 3, as well as heat-insulated: air ducts 30 with air flow regulators 29.

The device operates as follows.

According to the first variant of open beds, the habitats of the worms are heated as follows: the sun's rays through the light-penetrating wall 10 heat the light-absorbing surface 11 inside the chamber 6, which in turn heats the air and heat accumulators 7. The chamber 6 is protected from heat loss by an external heat-insulating coating 12. The accumulated heated air from the upper part of the chamber 6 enters through the suction pipe 3 through openings 4 into the pipeline 1, passing through it, heated air through openings 2 enters the base of the garden 1 4 and heats the habitats of the worms in the garden. To create accelerated air movement in the pipeline 1, a high exhaust pipe 5 (for example, about 2 meters high) is installed on the north side, at the top of which a deflector 13 is attached, and a pipe 9 is installed at the side of the exhaust pipe 5 at an angle to it, from which chamber 8 hot air enters, accelerating the movement of air (movement by the principle of an ejector jet pump) passing through the pipe 1 from the chamber 6. To heat the habitats of the worms at night, heat accumulators 7 can be installed in the chambers 6 and 8, which store in the frying pan ie daytime heat from the sun, and after sunset this heat.

Air temperature control during freezing or during the onset of prolonged cold weather is carried out by partially or completely closing the openings 4 on the suction pipe 3. In winter, the suction pipe 3 and exhaust pipe 5 are insulated and closed ”, preventing cold air from entering pipeline I and thereby allowing the worms to cool. In springtime, in sunny weather, if the temperature in the soil of the bed 14 is lower than the temperature in the heating chamber 6, the suction pipe 3 and exhaust pipe 5 are opened, while the soil is heated in the habitats of the worms and, accordingly, the increase in the time of active life, which is determined by indirect indicators. For example, one of the indirect indicators of the vital activity of earthworms is the production of coprolites per day. It is known that at a temperature of 5 degrees C coprolites produced 362 mg. dry weight, and at a temperature of 15 degrees C to 2353 mg., i.e. 6.5 times, therefore, heating the soil to 30-40 degrees C tens of times will increase the vital activity of worms and, accordingly, plants forming mutually beneficial symbiosis.

The worms are protected from earth-moving predators (moles) by installing a fine mesh 15 above the pipeline 1, behind which they are saved, and the worms located in the region of the pipeline 1 can hide in it, for this hole 2 in the pipeline 1 is made with a diameter larger than the diameter of the worms. Around the pipeline 1 and above it is laid a layer of organic matter (branches, branches, wood waste, old grass, etc.) 21, impassable for moles and also contributing to the shelter of worms.

To protect against mice and birds, beds 14 are placed on top of food prepared for worms (for example, food waste), boxes 17 with holes 18 with a diameter larger than the diameter of the worms in which they can hide. On top of the boxes 17 are closed by lids 16, which serve as protection against birds, as well as for collecting worms. Additionally, rods 19 are inserted into the bottom of the drawers 17 in the form of a metal brush, the distance between which is less than half the diameter of the mouse hole. At the ends of the rods 19, thickenings 20 are made, allowing, if necessary, to raise the soil together with the worms 22 and transfer to another place during feeding.

The collection of worms is carried out by creating a vibration of the soil in the area where they live, as a result of which they are collected through the openings 18 into boxes 17, the cover 16 is removed and, for example, worms that are clean of soil are collected using a suction device.

Temperature control is carried out according to the readings of temperature sensors 27 installed in the heating chambers 6 and 8, as well as directly in the habitats of the worms in the bed 14. The temperature of the habitats of the worms is controlled by partially closing or opening the holes 4 on the suction pipe 3 or by regulators 29. When humidification of the hot condensate, settling in the underground pipeline 1, increases the efficiency of heat transfer to the beds 14 and moistens the habitats of the worms 22 and plant roots.

According to the second option, with closed beds - a greenhouse (Fig. 7), hot air is taken from the greenhouse and through the suction pipe 3 and the underground pipe 1 enters the exhaust pipe 5. To accelerate the movement of air (enhance the action of the ejector jet pump), the air enters the pipe 9 is fed from the upper most heated part of the greenhouse, and at the junction of the pipe 9 and the exhaust pipe 5, a narrowing is established.

According to the third option (Fig. 8), a solar energy concentrator is installed away from the beds 14, consisting of a sphere-shaped reflective surface 31, which concentrates the sun's rays at one point located on the suction pipe 3, closed by light-penetrating walls 10, in this case, the temperature of the air heating can reach several hundred degrees. Hot air from the pipe 3 through the insulated air ducts 30 is sucked into the pipe 1, while the temperature in each of the beds 14 is controlled by regulators 29 (made, for example, in the form of rotary dampers installed in the duct 30), which allows you to create for each bed (each species of medicinal plants participating in symbiosis with worms 22) their optimal thermal regime, and this will increase the yield of raw materials for the created drugs and, accordingly, their effectiveness.

The combination of the type of feed and the type of plants grown allows you to program changes in the spectrum of antibiotic substances obtained from actinomycetes (an essential component of the intestinal microbiocenosis of earthworms), and the regulation of heat, moisture and the content of aerosols in the supplied air increases the productivity of the device with minimal operating costs.

A side effect is a several-fold increase in the yield of agricultural plants, as growing worms in the presence of plant roots is mutually beneficial cooperation, which is inevitably accompanied by a multiple increase in productivity and improving product quality, because fresh excrement of worms is an ideal environment for microorganisms and plants.

Such a constructive solution allows us to make the device simple, adjustable and efficient.

Claims (4)

1. An artificial nesting device for earthworms, including an underground pipeline, a grid with cells of less than half the diameter of wormholes above the underground pipeline, lidded boxes laid on the soil in the upper layers of the beds, in the bottom of which holes have been made, and rods entering the soil are installed below , characterized in that the lower part of the pipeline contains holes, at one end of the pipeline there is a suction pipe, and at the other end there is a chimney, where both the chimney and suction th nozzle includes a heating chamber, the heating chamber on the south side have svetopronikayuschuyu wall inside a light-absorbing surface and the outside have a heat-insulating coating. 2. The device according to p. 1, characterized in that the exhaust pipe is additionally equipped with a deflector. 3. The device according to p. 1, characterized in that inside the heating chamber at the suction pipe there are heat accumulators, an evaporation bath and a cotton wick immersed at one end in an evaporation bath. 4. The device according to p. 1, characterized in that it further includes temperature sensors installed in the heating chamber at the suction pipe, in the exhaust pipe and in the bed.

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