UA132807U - FLOATING SELF-PURCHASE FILTER FOR IRRIGATION SYSTEMS - Google Patents

Abstract

The floating self-cleaning filter for irrigation systems contains a floating pontoon with a space frame, which has a filter drum with a mesh working surface and a water intake inside. The filter is equipped with a mechanism for rotating the filter drum and at least one comb of water nozzles. The mechanism of rotation of the filter drum is made on the basis of a hydraulic turbine. Part of the water nozzles is designed to interact with the blades of the hydraulic turbine and is intended for its drive.

Description

The useful model belongs to the structural elements of irrigation systems for irrigating agricultural land, and more specifically to the structural elements of sprinkler agricultural machinery, namely floating self-cleaning filters for water intake from open water bodies.

In areas with insufficient moisture, irrigation systems and sprinkler agricultural machinery are widely used, which are able to provide the necessary replenishment of moisture in the soil. By watering with small rates, you can constantly maintain the necessary soil moisture, creating the most favorable conditions for the growth and development of agricultural crops. Irrigation agricultural equipment turns water flow into raindrops, directs them to a certain distance and evenly distributes them over the irrigation area.

The effectiveness of sprinkler equipment is assessed by the uniformity of water distribution over the irrigation area (by the quality of the rain). The water flow of the necessary power is created by the sprinkler pump unit, and its special nozzles create high-quality rain. The main condition for the long-term and reliable operation of both special nozzles and the water pump is the purity of the water supplied to them, the absence of inclusions in it that can clog the holes of the nozzles or disable the pump. Therefore, the water intake pipe of the pump is usually equipped with a reliable filter capable of ensuring continuous purification of the water supplied to the pump during the operation of the sprinkler. In the conditions of flat terrain and large cultivated areas of agricultural crops, the most attractive and economically expedient is the extraction of water for irrigation from open bodies of water (rivers or streams, ponds, open irrigation canals, etc.).

As a rule, such reservoirs in the coastal zone accessible for water intake are overgrown with algae and are not deep enough, in addition, the presence of living fauna (for example, fish, including fry), which must be preserved in the reservoir during water intake for watering In such conditions, water intake should be carried out from the surface layer of the reservoir, the filter hole of the water intake should be quite small, because of which the filter needs constant cleaning during operation. It is possible to provide the above with the simultaneous movement of sprinkler equipment along the banks of reservoirs by using floating self-cleaning filters.

The well-known is the "Sifting device" (invention patent of the Russian Federation Mo 2532183,

VOTO 35/05, publ. 27.10.2014), intended for the separation of liquid components from suspension.

The device of the present invention is a self-cleaning filter by design, which has a floating pontoon with a space frame, on which a pump, a vibrator and a conical submersible tank with a trapezoidal cross-section are fixed, with the larger base at the top. The walls of the tank made of sieves are connected to the vibrator with the help of special rods, and the water intake of the pump is located at the bottom of the underground tank.

When separating suspensions consisting of a liquid and purely solid crystalline phase, the known device well separates the liquid phase passing through the sieves of the tank. At the same time, it is also constantly self-cleaning in the process of work due to providing the sieves with vibration, which cleans the meshes of the sieves from solid crystalline particles that have settled on them. But for filtering water from open water intended for use in sprinklers, such a filter is not suitable, because such open water contains not only hard crystalline particles such as small stones and sand, but also a large amount of soft algae, especially filamentous , from which it is practically impossible to clean the mesh of sieves clogged by vibration.

Also known is the rotary filter "Vimegzsteep", designed for taking water from open sources of the VIM5SAMA brand (Prospect of the company "Repiai", Australia, 9 2015, Repiai), which has a floating pontoon with a spatial frame, on which a filter drum with a mesh is installed a working surface and a water intake pipe inside, while the self-cleaning filter is equipped with an electric drive for rotating the filter drum and a cleaning comb of water nozzles installed on the frame, which are directed outwards to the mesh working surface of the filter drum.

The famous Vimegesteep rotary filter provides the possibility of taking water for irrigation systems from the uppermost layers of open water, as it is installed on a floating pontoon with a space frame in such a way that its filter drum with a mesh working surface can be partially submerged in water. And equipping the filter drum with an electric rotation drive and a cleaning comb of water nozzles, which from the outside with water pressure wash off deposits from the mesh working surface during its rotation during the filter operation, ensure self-cleaning of the rotary filter and its reliable operation and continuous cleaning of the water supplied during operation in sprinkler pump.

The main disadvantage of the well-known rotary filter "Vimegesteep" is its lack of safety and reliability of operation due to the electric drive of rotation of the filter drum, 60 because electricity and water do not mix well in structures, due to which such structures in conditions of constant humidity are prone to electrical breakdowns with negative consequences not only for operational suitability of the equipment, but also for the safety of the service personnel. The very need to supply additional electrical power to the floating self-cleaning filter creates significant inconveniences. In addition, the external comb of the water nozzles, although capable of washing away deposits, including filamentous algae, from the mesh working surface with the pressure of water, but cannot ensure their complete absence in the water after filtration. It is impossible to completely exclude the passage of at least a small fraction of filamentous algae through the mesh work surface into the filter drum under the action of the external water pressure from the comb of the water nozzles, which somewhat reduces the quality of filtration.

The closest in terms of technical essence and the result achieved is the "Self-cleaning unit for filtering irrigation water" selected as the closest analogue (patent of the United

of the United States Mo 8652324, VO10 33/073, 33/50, 33/80, 35/05, 33/06 (2006.01), publ. 18.02.2014), which has a floating pontoon with a spatial frame, in which a filter drum with a mesh working surface and a water intake pipe is installed inside. Also inside the filter drum is a comb of water nozzles, which are directed to the inner side of its mesh working surface. A V-belt transmission from an electric motor is provided to drive the filter drum.

Installing a comb of water nozzles inside the filter drum in the closest analogue increases the quality of filtration, because in this case, the action of the pressure of the cleaning water from the inside prevents filamentous algae from entering the internal volume of the filter drum, knocking them out from the mesh of the mesh working surface of the filter drum.

However, the rotation drive of the filter drum from the electric motor does not give the prototype the opportunity to get rid of the main shortcomings, namely insufficient safety and reliability of work, as well as the need for an electrical power supply.

The basis of the useful model is the task of creating a safer and more reliable floating self-cleaning filter for irrigation systems, the operation of which would not require electrical power.

The task is solved by the fact that in a floating self-cleaning filter for irrigation systems, which has a floating pontoon with a spatial frame, in which an equipped

With a rotation mechanism and at least one comb of water nozzles, a filter drum with a mesh working surface, and a water intake nozzle inside, while the rotation mechanism of the filter drum is made on the basis of a hydraulic turbine, and part of the water nozzles is adapted to interact with the blades of the water turbine and is intended for its drive.

The implementation of the mechanism of rotation of the filter drum based on the hydraulic turbine, as well as the use of part of the water nozzles to drive the hydraulic turbine by connecting them with the blades of the hydraulic turbine, makes it possible to get rid of the need for electric power for the operation of the self-cleaning filter for irrigation systems, due to which the safety and reliability of the operation of the floating self-cleaning filter for irrigation systems.

Thus, the set of features and each of the features of the proposed useful model ensure the achievement of the set task, namely the creation of a safer and more reliable in operation floating self-cleaning filter for irrigation systems, the operation of which does not require electrical power.

Figure 1 shows a general view of a floating self-cleaning filter for irrigation systems; in Fig. 2 - view A in Fig. 1; in Fig. C - view B in Fig. 2.

The floating self-cleaning filter for irrigation systems has a floating pontoon of several floats 1 and a spatial frame 2, which is designed to combine the floats 1 into a single floating platform, as well as to install in it horizontally with an adjustable immersion depth the submersible filter drum 3 with a cylindrical mesh working surface 4 To adjust the depth of immersion of the filter drum Z, four regulating mechanisms 5 are provided, which are equipped with a spatial frame 2. Inside the filter drum Z, along its horizontal axis, there is a water intake nozzle 6, equipped with a water receiver 7 for taking purified water from the lower part of the filter drum 3. Located horizontally water intake pipe 6, on one side is equipped with an inclined section 8 for connection to the water supply pipe of the pump assembly of the sprinkler machine (not shown in the drawings). Inside the filter drum 3 is an internal comb 9 of water nozzles 10. Also, the floating self-cleaning filter for irrigation systems is equipped with a filter drum rotation mechanism. This mechanism consists of a hydraulic turbine 11 installed on the frame 2, which is connected to a gear wheel 12 rigidly installed on the end surface of the filter drum 3. An external comb 13, part of the water nozzles 14, which is directed to the blades of the hydraulic turbine 11, is also installed on the frame 2 and are intended for its drive, and the rest is directed at an acute angle to the outer surface of the filter drum for its additional cleaning. The inner comb 9 and the outer comb 13 of the water nozzles are connected to the pressure pipeline (not shown in the drawings) of the sprinkler pump unit.

A floating self-cleaning filter for irrigation systems works as follows. The floating pontoon of the self-cleaning filter is installed in an open reservoir, the inclined section 8 of the water intake nozzle b is connected with the help of an elastic coupling to the water supply nozzle of the pump unit of the sprinkler machine (not shown in the drawings), and the inner comb 9 of the water nozzles 10 and the outer comb 13 of the water nozzles 14 connect to the pressure pipeline (not shown in the drawings) of the sprinkler pump unit.

Fill all water pipes with water. With the help of regulating mechanisms 5, the immersion depth of the filter drum 3 is set, which depends on the depth of the open body of water, taking into account that the nominal depth of immersion is such a position of the filter drum at which its horizontal axis coincides with the surface of the open body of water, or has a slight (no more than 1/ 5 diameter of the filter drum) deeper immersion. Next, turn on the pump assembly of the sprinkler machine and after its output to the nominal mode of operation, turn on the supply of high-pressure water to the inner comb 9U of the water nozzles 10 and the outer comb 13 of the water nozzles 14. At the same time, the initial output of the pump assembly of the sprinkler machine to the optimal mode of operation is carried out due to intake by the receiver 7 of purified water that has passed through the mesh working surface 4 of the filter drum 3, and the supply of this water through the water intake pipe 6 and through the water supply pipe to the pump assembly of the sprinkler. After supplying high-pressure water to the comb 13 of the water nozzles 14, part of which is directed to the hydraulic turbine 11, the interaction of the water jets of the part of the nozzles 14 with the blades of the hydraulic turbine 11 begins with the formation of a torque of force, which leads to the rotation of the wheel of the hydraulic turbine 11 and installed on one the shaft of the gear wheel 12 together with the filter drum 3, on the end surface of which the gear wheel 12 is rigidly installed. Due to the rotation of the filter drum 3 on the surface

The previously submerged part of the mesh working surface 4 rises from it, on which algae and other polluting inclusions from the water of the open reservoir began to settle.

Moving up, the part of the mesh working surface 4 that has risen from the water is exposed to the water jets of the nozzles 10 of the internal comb 9, which act on deposits from the inside of the filter drum C, knocking them out of the mesh working surface 4.

If any part of the deposits (most often filamentous algae) is retained outside on the mesh work surface 4, it is washed away by the water jets of that part of the nozzles 14 of the outer comb 13, which are directed at an acute angle to the work surface 4, and under the action of which the deposits fall upon further rotation of the filtering drum 3. Self-cleaning of the floating filter for irrigation systems is carried out in this way. If the nozzles 10 of the inner comb 9 are sufficiently efficient and there is no need for additional cleaning of the mesh working surface 4, the part of the nozzles 14 of the outer comb 13, which are intended for such additional cleaning, can be turned off, due to which the efficiency of the sprinkler can be slightly increased cars.

The implementation of a technical solution based on a useful model allows for the creation of a construction of a floating self-cleaning filter for irrigation systems that is more reliable in operation and safer for service personnel, the operation of which does not require electrical power.

At the same time, the creation of a structure according to a useful model is possible from well-known materials on the equipment common in the production of irrigation equipment and does not require the use of the latest materials and technological processes.

Claims (1)

UTILITY MODEL FORMULA A floating self-cleaning filter for irrigation systems comprising a floating pontoon with a space frame in which is mounted a filter drum with a mesh working surface and a water intake pipe inside, the filter being equipped with a mechanism for rotating the filter drum and at least one comb of water nozzles, characterized in that that the filter drum rotation mechanism is made on the basis of a hydraulic turbine, and part of the water nozzles is made with the possibility of interaction with the blades of the hydraulic turbine and is intended for its drive.