RU2010516C1 - Earthworms growing apparatus - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: apparatus has roof and frame, which are secured in guides by means of rollers for displacement in horizontal plane. Roof and frame are connected at both sides with winches through cables. Thermal relay disposed in a trench is united with drive of winches, which are connected with roof. Frame is connected with carcass of hollow walls of aerators through winches. Upper part of aerators is formed as inverted hermetically sealed trough, remaining part is defined by perforated plates. Hollow walls are connected with chamber having fan, through drain pipes and branch pipes, extending through water body in basin. Guides are rigidly mounted on frame. Tubular carriage with sprinkling nozzles is mounted in guides on rollers. Carriage is connected with winches and flexible pipes, which are suspended on cables. Carriage is in contact with microswitch united with winch drives. Aerator may be formed by branch-pipes, arranged in several rows in equally spaced relation and connected with frame at an angle of 90 deg. EFFECT: increased capacity and enhanced reliability in operation. 2 cl, 6 dwg

Description

 The invention relates to agriculture and can be used for growing earthworms.

 A device for growing earthworms, including boxes with a capacity of 30-80 liters. In the boxes, earthworms and soil with a nutrient medium for growing them are placed. Several boxes with a height of 200 mm are stacked and installed on the storage floor with an interval of 50 ml between the side walls of the boxes of adjacent stacks. The nutrient medium in each drawer is covered on top with paper or plastic film. There are openings in the walls and bottom of the drawers for the passage of air and seepage of moisture, the diameter of the holes is 5-20 mm. The surface occupied by the area of the holes, 15-40%.

 The disadvantages of this device are low productivity, high complexity, in addition, many boxes are required.

Famous Hungarian technology for growing earthworms in old concrete silo trenches. Stacks of substrate 1.5 m high are formed in trenches; stacks of organic substrate are covered with straw. 1 million worms are introduced per 10 tons of organic substrate. The processing process is 3 months. at a humidity of 80% at 20-30 ° ^C. From the 2 t 1 t manure obtained vermicompost 1.5-3.0 t / ha equivalent to 40-50 t / ha of manure.

 Known Japanese technology for the maintenance of earthworms in buried pools. During the day, 40 tons of manure are processed.

 Known technologies have the following disadvantages. When manure stacks are formed, air and water penetrate well only in the upper and lateral sides of the stack. Air and water do not enter the deepest layers of the organic substrate, known devices have low productivity, poor conditions for growing earthworms.

 The aim of the invention is to increase productivity, simplify operation and improve the conditions for the maintenance of earthworms.

This is achieved by the fact that the roof and the frame with the help of rollers are fixed in the rails and made with the possibility of movement in the horizontal plane. The roof is connected to the swan on both sides. A thermal relay is installed in the trench, interlocked with the winch drive, with the help of winches the frame is connected to the hollow perforated vertical partitions dividing the trench into sections, their upper 1 / 3-1 / 2 part is made in the form of an inverted hermetic gutter, the rest is made of perforated plates , hollow partitions are connected to a chamber equipped with a fan, through drainage pipes and nozzles that are passed through a layer of water in the pool, guides are rigidly fixed on the frame, a tubular carriage is installed in them and sprayed from nozzles, the carriage is connected to the winch and coiled tubing, suspended on a rope, the carriage is contacted with the microswitches, interlocked with the actuators winches. The aerator-miner is made of nozzles mounted on several rows at an angle of 90 ^about .

 The novelty of the claimed technical solution in comparison with the known ones is due to the fact that due to the thermal relay interlocked with the winch drive connected to the movable roof, the microclimate is improved in the trench, which helps to improve the conditions for the maintenance of earthworms, and the operation of the device is simplified. Full perforated partitions as they move upward form mines, which contribute to the improvement of aeration of air and moisture in all layers of the nutrient medium, which allows to improve the conditions of worms. Hollow perforated partitions contribute to the periodic growth of the nutrient medium with a layer of 2-3 m without changing the biohumus, and also due to the use of a loader-reloader when loading the nutrient medium into the trench and unloading the biohumus in vehicles, productivity increases.

 In the study of the claimed technical solution for patent, scientific and scientific-technical materials, such a combination of features was not found that allows us to judge the novelty and materiality of the features.

 In FIG. 1 shows a plant for growing earthworms, cross section; in FIG. 2 - the same, top view; in FIG. 3 - the same, longitudinal section; in FIG. 4 - system of irrigation and aeration of the nutrient medium; in FIG. 5 - installation for growing earthworms, option; in FIG. 6 is a structural diagram of the interaction of nodes and parts.

 On the walls 1 of concrete trenches 2, guides 3 and 4 are installed. On guides 3 with the help of rollers 5, a movable cover 6 is installed, made of a translucent coating. A frame 7 is mounted on the guides 4 using the rollers 5. The roof 6 is connected to the winches 8 and 9 using the cables 10. The frame 7 is connected to the winches 11 and 12 using the cables 10. The roof 6 and the frame 7 are movable along the guides 3 and 4 in the horizontal plane. The winch 11 is equipped with an electric motor 13. On the roof 6, hooks 15 in contact with microswitches 16 and 17 are rigidly fixed. On frame 7, hooks 18 in contact with microswitches 19 and 20 are rigidly mounted. Thermal relay 21 is connected to electric motors 22 of winch 8 and electric motors 23 winch 9 using an electric circuit. Winches 24, equipped with an electric motor 25, are pivotally mounted on the frame 7. The winches 24 are connected to the metal frame 26 of the hollow vertical partitions 27 using ropes 28. The hollow partitions 27 are made of polymer materials, they are rigidly connected to the metal frame 26. The hollow vertical partitions 27 are divided the whole trench 2 into equal sections 29 and perform the function of mine-builders and aerators of the nutrient medium. They are made in the form of an inverted airtight trough, their upper 1 / 3-1 / 2 part is airtight, the rest is made of perforated plates. The hollow partitions 27 are connected to the chamber 30 and are equipped with a fan 31 through the drainage pipes 32, nozzles 33, which are passed through a layer of water in the pool 34. The drainage pipes 32 are connected to the upper base of the pool 34 using the nozzle 35. An electromagnetic valve 36 is rigidly fixed to the nozzle 35 Drain pipes 32 are connected in the lower base of the pool 34 by means of a pipe 37 and a pump 38. The pump 38 is equipped with an electric motor 39. The fan 31 is equipped with an electric motor 40. Guides 41 are rigidly fixed to the frame 7, they are mounted on rollers 42 a tubular carriage 43 with a spray nozzle 44. The carriage 43 is connected on both sides by cables 10 to the winches 11 and 12. The winch 11 is equipped with an electric motor 13, and the winch 12 is equipped with an electric motor 14. A hook 45 in contact with the microswitches is rigidly fixed to the carriage 43 46 and 47. A hook 48 is fixed to the frame 26, which contacts the microswitch 49 at the upper point. A level switch 50 is installed in the hollow partitions 27 and the pool 34. Above trench 2, a loader-loader 51 is installed, made of a gantry crane 52. On vehicles 53 a nutrient medium is transported, with a loader-loader 51 it is loaded into a trench 2. The level switch 50 is made of a float 54, a rod 55, an adjusting nut 56, microswitches 57. Electromagnetic taps 58 and 59 are installed in the pipe 37. An electromagnetic tap 61 is installed in the water supply network.

The water supply network 60 is connected to the spray nozzles 44 by means of a flexible hose 62, the hose 62 by means of rings 63 is suspended from the cable 64. The installation can be performed in another embodiment. The option (see Fig. 5) differs from the first one in that the aerator-miner 65 is made of the same type of nozzles 66 mounted on several rows at an equal distance from each other. In each row are rigidly and hermetically connected to the nozzles 66 of the tubular frame 67 at an angle of ⁹⁰ °. The nozzles 66 in the lower 2 / 3-1 / 2 part are made of perforated holes. The tubular frame 67 is connected to a chamber 30 provided with a fan 31. At the bottom of the concrete trench 2, a frame 26 is installed with hollow vertical partitions 27 dividing the trench 2 into equal sections 29. The cover 6 is open in the trench.

 The device operates as follows.

 To the concrete trench 2 on vehicles 53, a prepared nutrient medium for worms made from an organic substrate is delivered. Using a loader-loader 51, the nutrient medium from the vehicles 53 is loaded into the trench 2 so that all sections 29 are uniformly filled with the nutrient medium, and a thin layer of straw is covered on top of the nutrient medium. Then close the electric circuit supplying the electric motor 39 and the electric valve 59. The electric motor 39 rotates the blades of the pump 38. The pump delivers water from the pool 34 through the pipe 37 through the valve 59, the drain pipe 32. Water in the hollow partitions 27 is evenly distributed according to the principle of communicating vessels and moves from bottom to top.

Through the perforated openings in the vertical partitions, it penetrates into each section 29. As soon as the whole nutrient medium is saturated with moisture, the level switch 50 activates and closes the electric circuit supplying the electric tap 36, and opens the electric tap 59. At the same time, the water supply from the pool 34 stops, the electromagnetic valve 36 opens. Water from the concrete trench 2 moves through drainage pipes 32 to the pool 34. After moisturizing the nutrient medium, its mass is compacted and settles, and decreases in volume to 10%. In each section 29, 2-3 kg of earthworms (California) are poured. Worms creep into the nutrient medium, begin to grow, develop and multiply. The electric circuit supplying the electric motor 40 is closed. The electric motor 40 rotates the fan 31. The fan 31 creates excessive air pressure. Compressed air from the chamber 30 through the pipe 33 moves to the pool 34. Passing through the water layer, the air is enriched with oxygen and moisture and moves through the valve 36, the drain pipes 32 into the hollow partitions 27. Compressed air enriched with oxygen through the perforated openings of the partitions 27 of section 29, penetrates the pores of the nutrient medium where earthworms live. Aeration of the nutrient medium where earthworms live improves the respiration of earthworms, accelerates growth and development, and accelerates the processing of the organic substrate. The top layer of wet straw creates shading. Worms feel good in the dark. The rays of the sun do not penetrate through a thin layer of straw. Straw is a good porous material. Air penetrates freely through the straw. This has a beneficial effect on the growth and development of worms. The translucent coating of the lid 6 creates a greenhouse effect. Once the temperature of the air under the roof 6 exceeds 26 ^{° C,} thermal switch 21 is activated and closes an electric circuit feeding the electric motor 22. The electric motor 22 rotates the winch 8. The winch 8 by means of cables 10 and rollers 5 moves along the guide roof 6. Once the roof 6 moves to the proper point, with the help of the hook 15 it contacts the microswitch 16. The microswitch 16 opens the electric circuit supplying the electric motor 22. The movement of the roof 6 stops, fresh cool air penetrates flushes into the trench. Once the temperature lowered to less than 22 ^{° C,} thermal switch 21 is activated and closes an electric circuit feeding the electric motor 23.

 The electric motor 23 rotates the winch 9. The winch 9 with the help of cables and rollers 5 moves along the guides 3 of the roof 6 to its original position. As soon as the roof 6 is moved to the proper point by means of the hook 15, it contacts the microswitch 17. The microswitch 17 opens the electric circuit supplying the electric motor 23. The movement of the roof 6 is stopped. Earthworms multiply in the nutrient medium.

 The electric circuit supplying the electric motor 25 is closed. The electric motor 25 rotates the winch 24. The winch 24 by means of ropes 28 moves the frame 26 with perforated hollow vertical partitions 27 up to a certain height. Then, the electric circuit supplying the electric motor 25 is opened. In this case, the frame 26 with the partitions 27 hangs on the frame 7. The hollow vertical perforated partitions 27 perform the function of mine formers and aerators during periodic build-up of the nutrient medium. Then, the loader-loader 51 immerses the nutrient medium from the vehicles 53 into the trench 2 so that all sections 29 are uniformly filled with the nutrient medium, above the level of section 29 and from above the nutrient medium is covered with a thin layer of straw. Then close the electric circuit that feeds the electric motors 39 and 13 and the electromagnetic valve 58. In this case, the electric motor 39 rotates the pump 38 and supplies water from the pool 34 through the pipe 37, through the valve 58 through the flexible hoses 62 to the spray nozzles 44. The spray nozzles 44 are sprayed water and moisturize the nutrient medium in all sections 29, while the electric motor 13 rotates the winch 11. The winch 11 moves the tubular carriage 43 along the guides 4 by means of rollers 42. As soon as the carriage 43 moves to the proper point, 45 contacts the microswitch 46. The microswitch 46 opens the electric circuit supplying the electric motor 13 and closes the electric circuit supplying the electric motor 14. In this case, the electric motor 13 stops turning the winch 11, and the electric motor 14 rotates the winch 12 and the carriage 43 moves to the original position. When moving the tubular carriage 43 is spraying the nutrient medium. As soon as the carriage 43 moves to the proper point, the hook 45 begins to contact the microswitch 47. The microswitch 47 opens the electric circuit supplying the electric motor 14 and closes the electric circuit supplying the electric motor 13. In this case, the electric motor 14 stops rotating the winch 12, and the electric the engine 13 rotates the winch 11. The winch 11 moves the carriage 43, then all technological operations are repeated. After humidification of the nutrient medium, it condenses and settles within the level of sections 29. If excessive humidity of the nutrient medium appears, water flows through the drain pipe system 32 into the pool 34. Water for irrigation of the nutrient medium can be taken from the water supply network 60, for this purpose an electric circuit is closed, supply electric tap 61. In this case, water moves from the water supply network 60 through a flexible hose 62 through the tubular carriage 43 to the spray nozzles 44. The spray nozzles 44 spray water and irrigate the nutrient evenly Redu. Excess moisture from the medium is removed through the drainage pipe system 32 to the pool 34. As soon as the medium is sufficiently wetted, the electric circuit supplying the electromagnetic valve 61 is opened. The water supply for irrigation of the medium is stopped. As soon as the humidity of the nutrient medium decreases to 75%, the electric circuit supplying the electric motor 13 and the electromagnetic valve 61 is closed again. The humidification of the nutrient medium occurs in a similar way, as described previously. After a certain period of time, as soon as the nutrient medium is processed into biohumus, the electric circuit feeding the electric motor 25 is closed again. The electric motor 25 rotates the winch 24. The winch 24 with the help of ropes 28 moves the frame 26 with vertical partitions 27 up to a certain height. Then, the electric circuit supplying the electric motor 25 is opened. In this case, the frame 26 with partitions 27 hangs on the frame 7. Then, all sections 29 are loaded with a nutrient medium and the medium is moistened. As soon as the growth of the nutrient medium reaches the maximum height in the trench and the entire nutrient medium is processed into vermicompost, the electric circuit supplying the electric motor 39 is closed. The electric motor 39 drives the pump 38. The pump 38 from the pool 34 through pipes 37 and drainage pipes 32 transfers water to the concrete airtight trench 2. Water moves along the shafts formed by the hollow partitions 26. The filling of the airtight trench with water is regulated so that every centimeter of the vermicompost layer is behind full in 1-1.5 minutes. When mines are filled with water, water penetrates the pores of vermicompost and displaces the worms from all layers, worms cannot breathe without air in water and move up to the surface of the vermicompost. Worms, leaving the lower layers of the nutrient medium, rise higher and higher to the surface of the nutrient medium. On the surface of the worms they are collected, packed in boxes and sent for reproduction or for processing to meat flour. A sealed trench is poured with water to the level of the surface of the nutrient medium, this level can withstand 15-20 minutes. After collecting the worms from the surface of the biohumus, the electric circuit supplying the electromagnetic valve 36 is closed. Excess water moves along the hollow partitions 27, through the shafts, through the drainage pipe system 32 into the pool 34. The cables 10, which are attached to the carriage 43, are unlocked, moved and rigidly attached to the frame 7. As soon as all excess water is removed from the trench 2, close the electric circuit supplying the electric motors 25. The electric motors 25 rotate the winch 24. The winch 24 moves the frame 26 up to a certain height. As soon as the frame 26 moves to the proper point, it contacts the microswitch 49. The microswitch 49 opens the electric circuit supplying the electric motor 25 and closes the electric circuit supplying the electric motor 13 and 22. In this case, the electric motor 25 stops moving with the hoist 24 and cable 28 frame 26 with partitions 27. The electric motor 13 rotates the winch 11. The winch 11 by cable 10 moves the frame 7 mounted on the rollers 5 along the guides 4 outside the trench 2. As soon as the frame 7 moves hinging to the proper point, the hook 18 is in contact with the micro switch 19. The micro switch 19 opens the electric circuit supplying the electric motor 13 of the winch 11. At the same time, the electric motor 13 stops rotating the winch 11, the movement of the frame 7 is stopped. At the same time, the electric motor 22 rotates the winch 8. Using the ropes 10 and rollers 5, the winch 8 moves the roof 6 along the guides 3 outside the trench 2. As soon as the roof 6 moves to the proper point, the hook 15 contacts the micro switch 16, disconnects the electric circuit supplying the electric motor 22. The electric motor 22 stops rotating the winch 8. As soon as the microswitch 16 opens the electric motor 16, the electric motor 22 opens. The electric motor 22 stops turning the winch 8. Ka to only the microswitch 16 will open the electric motor 22, the electric motor 22 stops rotating the winch 8. The winch 8 stops moving the roof 6. As soon as the whole trench is freed from the roof 6 and the frame 26, the biohumus is unloaded into vehicles 53 using an organic fertilizer loader (POU-40) 51. Using vehicles 53, vermicompost is transported and scattered on the field. As soon as the biohumus from the trench 2 is completely overloaded by the loader-loader 51 into the vehicles 53 and with their help transported and scattered across the field, they close the electric circuit supplying the electric motors 14 and 23. The electric motor 14 rotates the winch 12. The winch 12 using a cable 10 moves the frame 7 to its original position. The electric motor 23 rotates the winch 9. The winch 9 with the help of cables 10 moves the roof 6 with the help of rollers 5 along the guides 3 to the initial position. As soon as the roof 6 moves to the proper point, the hook 15 is in contact with the micro switch 17. The micro switch 17 opens the electric circuit supplying the electric motor 23, the winch 9 stops moving the roof 6. As soon as the frame 7 moves to the proper point, the hook 18 contacts the micro switch 20. The micro switch 20 opens the electric circuit supplying the electric motor 14, and opens the electric circuit supplying the electric motor 25 of the winch 24. In this case, the electric motor 14 stops rotation s winch 12. The winch 12 stops moving frame 7. The winch 24 moves the frame 26 to the initial position.

 In the embodiment (see Fig. 5), the installation works in the same way as in the first embodiment, but the hollow tubular frame 67 is installed on the bottom of the trench so that the lower base of the holes of the nozzles 66 are installed above the holes of the drain pipes 32, and the nozzles 66 and the frame are filled 67 nutrient medium. When lifting the frame 67, the nozzles 6 form a shaft for aeration of humidification and drainage of the nutrient medium.

 The use of the invention in the national economy of the country can improve the conditions for growing earthworms, accelerate their growth and development and increase productivity. (56) Gorodnitsky N.M. et al. Vermiculture and its effectiveness, K, 1990, Agriculture, Overview, UkrNIINPT, Series Agriculture, Agricultural Chemistry, Agricultural Reclamation, p. 24-25.

Claims (2)

 1. Installation for growing earthworms, containing sealed concrete trenches with a roof and an automated irrigation mechanism, characterized in that the roof and the frame mounted above it by means of rollers are fixed in rails with the ability to move in a horizontal plane by means of winches attached on both sides, with the drive of which has blocked the thermal relay installed in the trench, while the frame has a frame of hollow polymer partitions-mine-formers-aerators suspended on winches, upper 1 / 3 - 1/2 part of which is made in the form of an inverted airtight trough, and the rest is made of perforated plates, in addition, the aerator is equipped with a fan installed in the chamber and drainage pipes, the free ends of which are located in the pool, and the hollow partitions have nozzles, the free ends of which are located in the upper part of the pool, and the irrigation mechanism is made in the form of a tubular carriage with spray nozzles, which is installed in the rails, rigidly mounted on the frame, and connected on both sides by winches, and pipes suspended on a cable with the possibility of contacting with microswitches mounted on the frame, interlocked with a winch drive. 2. Installation according to claim 1, characterized in that the frame of the hollow polymer partitions-mine-aerators is made of a tubular frame and nozzles installed in several rows at an equal distance from each other, and the nozzles are rigidly and hermetically connected to the tubular frame at an angle of 90 ^o .

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