RU2447234C1 - Device for production of sapropel of natural moisture - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: device includes a floating base placed in a water reservoir with swing and hoist winches, a submersible dredging pump. To energise the floating base, the device comprises a power supply cable. A discharge pipeline, which connects the pump with an accumulating hopper placed on the shore of the water reservoir, is made of polyethylene pipes and has two parts, connected between themselves in the flange connection - the shore one and the one arranged in water. The discharge pipeline is connected to the dredging pump with a submersible unit. The part of the pipeline arranged in water is connected to the submersible pump in the submersible unit placed in a heated room of the floating base. The shore part of the discharge pipeline is placed in soil at the depth exceeding the depth of the possible freezing of the shore soil. The submersible part of the pipeline is placed in the water reservoir at the depth exceeding the depth of the possible freezing of water. The submersible part of the pipeline has detachable loading yokes fixed outside to give them negative buoyancy. The submersible unit is mounted on the floating base with the possibility of vertical displacement and fixation. The floating base is mounted on a pontoon or on two joined parallel pontoons. Lateral sides of the pontoon or pontoons are made at the angle of more than 45° to the vertical plane, the top of which faces the base. The power supply cable is made as submersible, equipped with a protective jacket and fixed on a submersible part of the pipeline. The accumulating hopper has heat insulation and a heating system or is installed in a heated room.

EFFECT: expansion of functional capabilities of the device due to provision of sapropel production at any time of the year.

4 cl, 6 dwg

Description

The invention relates to the mining industry and can be used for the extraction of natural moisture sapropel from the bottom of the reservoir.

A known method of producing sapropel fertilizer described in the patent for invention RU No. 2336253, which is carried out by a device containing a dredger equipped with a bucket, or a grab or pneumatic chamber pump, through which from the bottom of the lake they carry out the extraction of sapropel with natural humidity ashore through the pipeline. The device also contains a storage hopper, in the upper part of which a mesh filter is installed, through which a crude sapropel is passed for cleaning from foreign impurities, while the hopper is equipped with a screw dispenser that feeds purified sapropel with natural moisture into a continuous twin-shaft mixer. The supply of sapropel in the storage hopper eliminates the possibility of getting into it various impurities brought in by the wind, which was the case in the prototype, and prevents significant oxidation of the sapropel by reducing its contact surface with air.

This device does not allow the extraction of sapropel in the autumn-winter period, which significantly reduces the production efficiency, since the downtime for reasons of freezing temperatures and ice cover is 5-6 months per year, i.e. about 40-50%.

The objective of the claimed invention is to provide a device that provides the ability to ensure the extraction of sapropel in the cold season, in the autumn-winter period.

The technical result is the expansion of the functionality of the device by ensuring the production of sapropel at any time of the year, in particular during freezing of a reservoir.

This is achieved by the fact that in a device for extracting natural moisture sapropel, including a floating base located in a pond with papillage and lifting winches placed on it, a submersible soil pump, a power supply cable, a pressure pipe connecting the pump to a storage hopper located on the shore of the pond, according to According to the invention, the pressure pipeline is made of polyethylene pipes and has two parts interconnected in a flange connection - a shore one and located in water, and a connection water with a soil pump in a submersible assembly, the onshore part of the pressure pipe being located in the soil at a depth exceeding the depth of possible freezing of the onshore soil, and the submersible part is located in the reservoir at a depth exceeding the depth of possible freezing of water, and the submersible part of the pipeline has removable cargo tanks fixed on the outside clamps to give it negative buoyancy, while the submersible assembly is mounted on a floating base with the possibility of vertical movement and fixation, and floating its base is mounted on the pontoon or on two pontoons connected to each other and located parallel to each other, and the lateral outer walls of the pontoon or pontoons are made at an angle of more than 45 ° to the vertical plane, the apex of which faces the base, and the power supply cable is immersed, equipped with a protective casing and fixed on the submersible part of the pipeline, while the storage hopper has thermal insulation and a heating system, located in a heated room. In addition, the protective casing is made in the form of a pipe made of polyethylene or metal having a round or square cross section and a curved section. The protective casing with the power supply cable located in it is connected to the submersible part of the pipeline by cargo or mounting clamps.

Figure 1 shows the device, a top view.

Figure 2 is the same side view.

Figure 3 shows a submersible assembly 10 with a protective cover for the cable located on top.

Figure 4 - embodiments of mounting clamps mounted on top of them with a protective casing for cable protection.

Figure 5 shows a submersible assembly 10 with a protective cover for the cable located on the side.

6 is an embodiment of mounting clamps with a protective casing fixed to them on the side to protect the cable.

The device includes a floating base 1 located in a pond with papilage winches 2 placed on it, a submersible soil pump 3, a pressure pipe 4 connecting a pump 3 with a storage hopper 5 located on the shore, made with thermal insulation and a heating system (not shown in the drawing) or placed in a heated room 6. The pressure pipeline is made of two parts interconnected in a flange connection - the coastal part 7 and part 8 located in the water. The pressure pipe 4 is made of polyethylene pipes. The execution of the pipes of the pressure pipe 4 from polyethylene pipes provides the ability to accurately adjust the buoyancy of part 8 of the pipe 4 using cargo clamps 9, giving it the necessary buoyancy, facilitated movement under water due to the ease of polyethylene. In addition, polyethylene has a water-repellent property, which contributes to a significant reduction in pressure loss in the pipeline compared to steel, withstands low temperatures up to -40 ° C, greater flexibility, which allows them to be conveniently operated underwater when moving the device. The choice of the grade of polyethylene (low, medium or high pressure - PE, PESD or PESP, etc.), the diameter of the pipes and wall thickness depends on the voltage (pressure) arising in the pipeline during its operation, as well as on the viscosity of sapropel and the length of the pipeline and the total lifting heights. Therefore, at low viscosity and low operating pressures, PE can be used, and at high viscosity, HDPE or HDPE.

To make part 8 of the pipeline 4 negatively buoyant, it is equipped with removable cargo clamps 9 fixed on the outside and placed uniformly along the length of the pipeline with a certain pitch. This embodiment will allow you to place part 8 of the pressure pipe under water, and in winter - under ice to prevent it freezing into ice and possible damage to the edge of the ice when moving. Since without a load the polyethylene pipeline has positive buoyancy (i.e. the polyethylene pipe floats on the water surface in a semi-submerged (empty pipeline) or 90% submerged (sapropel-filled pipeline) condition, the weight of the cargo clamps is calculated so that the pipeline when filling it sapropel did not float on the surface, but was slightly in contact with the bottom, and the pipeline should not be overloaded with clamps, since if the weight of the load (clamps) is excessive, excessive pressure will arise water to the bottom, the friction force of the pipeline against the soil will increase and it will be difficult to drag the dredger when moving.

Part 8 of the pipeline and the submersible pump 3 are interconnected in the submersible assembly 10, which is mounted on the pontoon 12 using detachable clamps (clamps) 22, which allow you to adjust the immersion depth of the submersible assembly 10 in water 17 by raising and lowering the vertical sections of the pipeline 23 and a vertical guide 24 of the immersion assembly 10 in the clamps 22. This allows you to select the required immersion depth of the pipe 8, taking into account the thickness of the ice, the height of the bottom vegetation, the depth of the water 17 in the reservoir. Lowering-raising the submersible assembly 10 to the desired depth is carried out with loosened clamps 22 using two portable deck jacks (not shown). The submersible assembly 10 thus includes a steel pipe having vertical and horizontal sections, a protective casing 16, a flexible section of the pipe 11, a transition cone 25, a vertical guide 24, fasteners for fixing the assembly 10 on the pontoon 12. Parts 7 and 8 of the pipeline 4 are interconnected by means of flanges (not shown in the drawing). The submersible assembly 10 has a flexible pipe 11 for connection with a ground pump 3. The coastal part 7 of the pressure pipe 4 is located in the soil at a depth exceeding the depth of possible freezing of the shore soil, and part 8 is located in the reservoir at a depth exceeding the depth of possible freezing of water, which will allow eliminate freezing of the pipeline and ensure uninterrupted supply of sapropel in the winter season.

The floating base 1 is mounted on the pontoon 12 or on two pontoons 12 connected to each other and located parallel to each other. The side walls of the pontoon 12 or pontoons 12 are made at an angle of more than 45 ° to the vertical plane, the top of which faces the base 1.

Papillage winches 2 are connected to anchor devices 13 located on the shore in the form of anchors by means of steel cables 14 of papillage winches 2.

To ensure power supply, the device has a power cable 15. Cable 15 is made of immersion, equipped with a protective casing 16, which is mounted on the immersion assembly 10 and the immersion section of part 8 of the pipeline 4 by means of mounting clamps 19. The side end of the cable 15 is inserted into the switchboard (not shown shown) of the floating base 1, and the coastal end of the cable 15 is connected to a power distribution board or substation (not shown in the drawing). The protective casing 16 is made in the form of a pipe made of polyethylene or metal having a round or square cross section with a curved section. For immersion and lifting of the pump 3 are lifting winches (not shown), mounted on a floating base 1.

The device operates as follows.

The floating base 1 is launched 17 after assembly on the shore 18 of the reservoir, the cables 14 of papillage winches 2 are connected to the shore anchor devices 13 in the form of anchors. On shore 18, polyethylene pipes are welded into a pipeline 4, the head of which, with the help of flanges 20, is joined on the shore with a submersible assembly 10 on which a protective casing 16 is rigidly fixed.

In the protective casing 16, the side end of the power supply cable 15 is inserted, and as the pipeline 4 is welded on the shore, cargo clamps 19 are mounted on it with a calculated step, to which the power supply cable 15 is attached.

As the pipeline 4 grows and the cable 15 is fastened on it, the pipeline 4 is pushed from the shore 18 to the water 17. In this case, the surface part of the submersible assembly 10 in the head of the pipeline 4 with the cable end 15 is kept afloat with the help of auxiliary floats or auxiliary watercraft (not shown ) As a result of this, water 17 does not enter the pipeline 4 and the pipeline 4, together with the cable 15 fixed to it, have weakly positive or neutral buoyancy and do not sink.

After the pipeline 4 is completely welded to the full design length, on the shore 18 along the pipeline 4 from the water edge 17 to the hopper 5, they dig a trench to a depth exceeding the depth of possible freezing of the soil 21. After that, the coastal part 7 of the pipeline 4 is laid in an dug trench and made backfilling the trench with soil.

The submersible assembly 10 with the submersible (now floating) part 8 of the pressure pipe 4 is led to the floating base 1 so that the submersible assembly 10 is brought under the bottom of the pontoon 12 and is between the pontoons inside the insulated part of the floating base 1. After that, the submersible assembly is rigidly fixed to the pontoon body 12, and the side end of the cable 15 is led into the switchboard of the floating vehicle, and the shore end is connected to the power switchboard or substation.

After connecting the cable 15 on the shore and supplying power, using papillon winches 2 tension cables 14 and shore anchors 13, the floating base 1 can move along the surface of the water within the area limited by the anchors 13. Due to the fact that the outer walls of the pontoons are at an angle, and anchor devices 13 in the form of an anchor of papillon winches 2 are mounted rigidly on shore 18, the floating base 1, due to the force created by the winches 2, is pulled to the anchors and can run over the ice edge and break it off at the expense of the weight of the floating base. The design of the floating base 1 and the pulling forces of the winches 2 are designed so that breaking off the ice edge and moving it over the water area is possible with an ice thickness of up to 20 cm. In severe frosts, when the ice thickness exceeds the calculated one, the craft will be pushed out by ice onto the ice surface beyond the existing slope of all the side walls of the pontoons 12 and will not be crushed by ice, as if the walls were vertical. At the same time, a part of the water space limited between the pontoons located under the heated technical room 26 of the floating base 1 is limited by transverse flexible walls (not shown) covering this space between the pontoons outside of freezing. Thus, the heat of the heated technical room 26 of the floating base 1 ensures that the water area under this room does not freeze, thereby making it possible for the flexible pipe to pass under the water, raising and lowering the soil pump 3. The submersible pump 3 is immersed in the thickness using a cargo winch (not shown) deposits of sapropel 27 and supplies the sapropel in a flexible section 11 of the submersible assembly 10, connecting the pump 3 with part 8 of the pressure pipe 4.

When sapropel is supplied to pipeline 4, air is forced out of it, the pipeline acquires negative buoyancy and is submerged under water.

The movement of the floating base 1 on the surface of the reservoir 17 is carried out by 4 papillage winches 2, cables 14 and coastal anchors 13. Coastal anchor devices 13, cables 14 and the tension of the winches and the weight of the floating base 1 are calculated for the force necessary to move the floating base 1 between anchor devices when covering the water area with ice of a certain thickness. When using conventional anchors, this is difficult to achieve due to the fact that the sapropel is in a viscous-fluid state and the anchors can move in the thickness of the sapropel with high tensile forces of the cables, while raising them from the thickness of the sapropel to move to a new place is quite problematic without a special floating floating means ( import or floating crane).

In order to reduce the resistance during movement of the pontoon 12 or pontoons 12 connected to each other and parallel to each other in winter, when the surface of the reservoir is covered with ice, the side walls of the pontoon or pontoons are made at an angle of more than 45 ° to the vertical plane, the apex of which faces the base, which allows pontoons or pontoons with inclined walls run into the ice edge, breaking it under its own weight. With a vertical arrangement of the outer side walls of the pontoon or pontoons, such a movement is impossible to carry out, because the pontoon will rest against the ice end and will not be able to overcome its resistance in the horizontal plane.

The protective casing 16 serves to exclude the possibility of damage to the cable 15 when working in the winter, for example, on the edge of the ice at the place where it emerges from the water or, for example, when the device is moved with a tension cable of a papillon winch 2.

The sapropel 27 is removed from the underwater reservoir and fed into the coastal storage hopper 5 using a submersible soil pump 3, which is lowered into the thickness of the sapropel 27 using a cargo winch (not shown) and, due to the vacuum created in the pump, sucks the sapropel , which is in a viscous-flowing consistency, and then, due to the generated pressure, on the other hand feeds it through the pressure pipe 4 to the hopper 5. At the same time, when working in cold weather, the requirement must be observed: throughout In all directions from pump 3 to hopper 5, sections of pipelines 11, 8, 7 and the submersible assembly 10 must not be exposed to frost or should be in the zone of positive temperatures. The temperature of the sapropel in the deposits in winter and summer is + 4 ° C, the temperature of the water under the ice does not fall below + 2 ÷ 3 ° C, the temperature in the technical heated room 26 is not lower than + 5 ° C. Thus, the pump 3, and the flexible pipe 11, and the submersible assembly 10, and the pipe 4 do not have contact with the negative outside temperature, which ensures the uninterrupted operation of the floating means 1 in the autumn-winter period.

The proposed device will expand the functionality and ensure the smooth operation of the device for the production of sapropel at any time of the year, including in winter.

Claims (4)

1. A device for the extraction of sapropel of natural humidity, including a floating base located in a pond with papillage and lifting winches, a submersible soil pump, a power supply cable, a pressure pipe connecting the pump to a storage hopper located on the shore of the pond, characterized in that the pressure head the pipeline is made of polyethylene pipes and has two parts interconnected in a flange connection - onshore and located in water and connected to a ground pump in a submerged unit, the onshore part of the pressure pipe being located in the soil at a depth exceeding the depth of possible freezing of the onshore soil, and the submersible part is located in the reservoir at a depth exceeding the depth of the possible freezing of water, and the submersible part of the pipeline has removable cargo clamps fixed to the outside to make it negative buoyancy, while the submersible assembly is mounted on a floating base with the possibility of vertical and horizontal movements and fixation, and the floating base the assembly is mounted on the pontoon or on two pontoons connected to each other and parallel to each other, and the side walls of the pontoon or pontoons are made at an angle of more than 45 ° to the vertical plane, the apex of which faces the base, and the power supply cable is immersed, equipped with a protective casing and fixed to submersible part of the pipeline, while the storage hopper is insulated and heated, or located in a heated room. 2. The device according to claim 1, characterized in that the protective casing is made in the form of a pipe made of polyethylene or metal having a round or square cross section with a curved section. 3. The device according to claim 1, characterized in that the protective casing with the power supply cable located in it is connected to the submersible part of the pipeline by cargo or mounting clamps. 4. The device according to claim 1, characterized in that each papillage winch is connected to anchor devices mounted on the shore of the reservoir.

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