RU202027U1 - DEVICE FOR WATER CLEANING AND SAPROPEL PRODUCTION - Google Patents

Abstract

The utility model relates to the technique of cleaning water bodies from humoid formations and sapropel extraction. The device for cleaning reservoirs and extraction of sapropel includes a suction-type intake working body, means for moving it and a device for removing the cleaning product, which are made in the form of a sealed chamber in which a drive drum is installed and a moving sleeve is fixed at one end, at the other end of which a pipe is fixed, in which also has drums with cables wound on them. One of the cables covers the torus, and the second is connected to the suction end of the sleeve fixed on the pipe wall, and holes are made in it on both sides of the torus to communicate the pipe cavity with the moving sleeve cavity. The inner walls of the torus are helically twisted relative to the central axis of the torus, and the degree of twisting of the inner walls of the torus should be such that the formation of a dense linear bundle, interacting tenaciously with the cable, is achieved. The technical challenge is to increase the service life and reliability of the device.

Description

The utility model relates to the technique of cleaning water bodies from humoid formations and sapropel extraction.

A device for cleaning water bodies is known, including a dredger with a suction pipe equipped with a scraper-type ripper and serving simultaneously to drain the cleaning product into the dredger, a drive and a current source [USSR AC for invention No. 1078002, IPC Ε02F 5/28, 1982 - analogue] ...

The disadvantages of this device are large dimensions in the presence of a floating craft as a means of moving the intake working body when changing mining sites and, therefore, poor maneuverability, the need for pumping equipment that provides suction and removal of the cleaning product.

Of the known technical solutions, the closest to the claimed technical solution (prototype) is a device for cleaning water bodies and extracting sapropel, which includes an intake working body of the suction type, a means for moving it and a body for removing the cleaning product, which are made in the form of a sealed chamber in which a drive drum is installed and a moving sleeve is fixed at one end, at the other end of which a pipe is fixed, in which drums with cables wound on them are also installed, and one of the cables covers the torus, and the second is connected to the suction end of the sleeve fixed on the pipe wall, and in it along both sides of the torus have holes that communicate the cavity of the pipe with the cavity of the moving sleeve [RF patent for invention No. 2028432, IPC No. 02F 5/28, 1995 - prototype].

The disadvantages of the prototype device are a relatively shorter service life due to uneven crushing of the torus walls during its rolling and the possibility of a working agent seeping through the inner walls of the torus during operation.

The task of the utility model is to increase the service life and reliability of the device.

To solve this problem, in a device for cleaning water bodies and extracting sapropel, which includes a suction-type intake working body, a means for moving it and a device for removing the cleaning product, which are made in the form of a sealed chamber in which a drive drum is installed and a moving sleeve is fixed on the other the end of which a pipe is fixed, in which drums are also installed with ropes wound on them, and one of the cables covers the torus, and the second is connected to the suction end of the sleeve fixed on the pipe wall, and holes are made in it on both sides of the torus to communicate the pipe cavity with the cavity of the moving sleeve, the inner walls of the torus are helically twisted relative to the central axis of the torus, and the degree of twisting of the inner walls of the torus should be such that the formation of a dense linear bundle interacting tenaciously with the cable is achieved.

The essence of the utility model lies in the fact that the inner walls of the torus are helically twisted relative to the central axis of the torus, and the degree of twisting of the inner walls of the torus should be such that the formation of a dense linear bundle interacting tenaciously with the cable is achieved.

The first new feature, consisting in the helical twisting of the inner walls of the torus, allows the claimed technical solution to achieve new properties, which consist in achieving uniform crushing of the entire surface of the torus and achieving a higher density of the inner walls of the torus. The second new feature, which consists in the fact that the degree of twisting of the inner walls of the torus should be such that the formation of a dense linear bundle coherently interacting with the cable is achieved, allows the claimed technical solution to achieve a new property, which consists in achieving the optimal mechanical structure of the inner walls of the torus, allowing sufficiently tenacious interact with the cable and not reach overstress and the exit of the inner walls of the torus beyond the limits of linear equilibrium. These new features and properties are absent in the known technical solutions and allow the claimed technical solution to achieve the effects of increasing the service life and reliability of the device.

The foregoing allows us to assert that the proposed technical solution meets the criteria of the invention "novelty" and "inventive step".

FIG. 1 schematically shows a general view of the proposed device for the purification of reservoirs and the extraction of sapropel.

Device

The device for cleaning reservoirs and extracting sapropel contains a sealed chamber 1, communicated with the system 2 for supplying a working agent, a drive drum 3 with a cable 4 wound around it is installed in the chamber and a sleeve 5 is fixed at one end. At the other end of the sleeve 5, an intake working body made in the form of a pipe 6, in which two drive drums are installed: one 7 with a rope 8 wound on it, the free end of which covers the torus 9 and is attached to the inner wall of the pipe 6; another drum 10 is installed closer to the suction end of the pipe 6, a rope 11 is wound on it, passed through the sleeve 12 and fixed with slings 13 at the suction end of the sleeve 12. The sleeve 12 is fixed at one end on the inner wall of the pipe 6 between the drum 10 and the suction end of the pipe 6. The cables 14 of the drums 7 and 10 are connected through the hollow shaft of the drum 3 to the current source 15. In the wall of the pipe 6, on both sides of the torus 9, holes 16 and 17 with valves are made. A discharge pipe 18 emerges from the sealed chamber 1. The inner walls 19 of the torus 9 are helically twisted relative to the central axis of the torus.

Device operation

A device for cleaning reservoirs and sapropel extraction works as follows. The device, together with the compressor, is transported to the reservoir by motor transport or watercraft. By system 2, the working agent (gas) is pumped through the sealed chamber 1 into the sleeve 5. The sleeve 5, being filled, unfolds in length and at its end moves the pipe 6. The working agent, entering the pipe 6 through the hole 16, moves the torus 9 by the action of the jet and straightens the sleeve 12. At the same time, cables 8 and 11 are unwound from the drums 7 and 10. After the pipe 6 is completely out of the sleeve 5, the supply of the working agent is stopped. The rope 8 is wound with the drum 7 and the torus 9 is pulled to it. As a result, a vacuum is created in the pipe 6, sapropel is sucked into it through the end of the sleeve 12. The rope 11 is wound with the drum 10 and the sleeve 12 is turned inside out. The sapropel is squeezed out through the hole 17 into the cavity of the sleeve 5. By rotating the drum 3, the sleeve 5 is pulled to the sealed chamber 1 and the sapropel is squeezed into the outlet pipe 18. Then, the working agent is fed into the sleeve 5, and the cycle is repeated ... The inner walls 19 of the torus 9 are helically twisted relative to the central axis of the torus, and the degree of twisting of the inner walls 19 of the torus 9 is such that the formation of a dense linear bundle interacting tenaciously with the cable 8. When the working agent moves the torus 9 by the action of its jet, it should be noted, according to the circuit in FIG. 1, that the torus 9 moves by rolling to the right, unwinding the cable 8 from the drum 7. When the torus 9 rolls to the right from the left side of the torus 9, the outer walls of the torus passing into the inner walls 19 begin to twist, and on the other side (right) of the torus 9, the inner walls 19 passing into external ones begin to unwind. When the supply of the working agent is stopped, the cable 8 is wound with the drum 7 and the cable 8 begins to pull the torus 9 to the left side, while rolling to the left from the right side of the torus 9, the outer walls passing into the inner walls 19 begin to twist, and on the left side the inner twisted walls 19 torus 9, passing into external ones, begin to unwind.

The use of the proposed technical solution, in comparison with the prototype device, makes it possible to increase the service life of the device due to uniform crushing and wear of the torus walls during operation, as well as to increase the reliability of the device in operation by reliably preventing leakage of the working medium through the inner walls of the torus.

Claims (1)

A device for cleaning reservoirs and extracting sapropel, including a suction-type intake working body, a means for moving it and a device for removing the cleaning product, which are made in the form of a sealed chamber in which a drive drum is installed and a moving sleeve is fixed at one end, at the other end of which a pipe is fixed, in which drums with ropes wound on them are also installed, and one of the ropes covers the torus, and the second is connected to the suction end of the sleeve fixed on the pipe wall, and holes are made in it on both sides of the torus that communicate the pipe cavity with the cavity of the moving sleeve, characterized in that the inner walls of the torus are helically twisted relative to the central axis of the torus, and the degree of twisting of the inner walls of the torus should be such that the formation of a dense linear bundle, tenaciously interacting with the cable, is achieved.

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