RU2059048C1 - Facility for extraction of lake ooze - Google Patents

Abstract

FIELD: underwater extraction of oozy soil, particularly extraction and packaging of sapropel. SUBSTANCE: device has floatable base with hydrocompressor and hydraulically driven lifting device. Pumping device is attached to the lifting device with cables. Pumping device is made in the form of pneumatic blower with working cavity open to cavities of rarefaction and excessive pressure of the hydraulically driven compressor through distributing device. Pumping device is equipped with outlet pipeline. EFFECT: better quality, ecologically pure technology, decreased labor consumption, decreased cost, enhanced reliability, wider application range. 3 cl, 3 dwg

Description

 The invention relates to underwater mining of silty soils and can be used for the extraction and packaging of sapropel.

A device containing a floating base, a vertical pipe attached to the latter with the possibility of vertical movement, the lower end of which is located below the level of sludge in a reservoir, a submersible pump, the pressure pipe of which is connected to the consumer of the sludge, as well as a lifting device for vertical movement of the pipe [1]
The disadvantages of this device include the fact that with a large depth of development, the length of the vertical pipe increases, the carrying capacity of the floating base and the lifting device, which leads to an increase in the metal consumption of the installation, and also limits the possibility of its movement across the water area in the working position; the intake part of the pipe is located vertically to the surface of the sludge layer, as a result of which water enters the cavity of the pipe when the unit is moving and the pumped sludge is flooded, which leads to an increase in energy consumption for pumping the liquid.

Closest to the proposed is a device [2] containing a floating base with a shaft attached to it, with the ability to rotate about its axis by 180 ^about . The lower end of the mine is equipped with a sludge receiver, consisting of a knee and a confuser, and is located below the level of silt in a pond. Inside the shaft there is a pumping electric pump, the suction part of which is submerged below the level of silt in the shaft to a depth corresponding to pressure losses, the magnitude of which is less than the pressure losses from the movement of silt in the shaft. The discharge pump discharge pipe is in communication with a sludge consumer (vehicle). In addition, the installation is equipped with a device for moving around the water area and a sludge level indicator in the mine.

 In the second embodiment, the installation is equipped with a pumping device in the form of a grab, and the upper part of the shaft is made in the form of a funnel.

 Installation works as follows.

 When pumping liquid or a grab from a mine, the level in it decreases, resulting in a pressure drop that is not enough to overcome friction pressure losses in the mine. When the unit moves in the direction corresponding to the direction of the intake, before the latter there is backwater due to the viscosity of the sludge. With this back pressure in mind, the pressure drop exceeds the above losses in the mine, as a result of which sludge flows from the bed to the mine.

 The advantage of the prototype over the analogue is that with a sudden stop of the working movement across the water area or a decrease in the amount of backwater at the entrance to the silt, the possibility of water entering the mine is excluded.

 The disadvantages of the prototype include the following.

 In the prototype, when the pumping device is made in the form of an electric pump, the sludge is mixed, as a result of which its natural structure is destroyed, the pore liquid enriched with organic ingredients is squeezed, which is discharged along with silt water during subsequent drying. As a result, the consumer properties of sapropel are deteriorating.

 When changing the depth of development, it becomes necessary to readjust the installation, which consists in changing the depth of immersion of the pump under the level of silt in the mine. This need is caused by a change in the shaft length and friction losses in it, and, consequently, in the available differential pressure provided by lowering the level in the shaft with a pump. At the same time, the value of the specified pressure drop should be selected such that the flow rate of sludge entering the sludge is equal to the capacity of the pump. Otherwise, the frequency of turning the pump on and off may exceed the permissible value. The above features of the operation of the installation complicate its operation.

 In the case when the pumping device is made in the form of a scooping device, the mined sapropel can be transported to the consumer only with the help of additional boats (barges) from which additional pumping (transshipment) is carried out, which leads to an increase in operating costs.

 When the scooping device is placed on a floating base (for example, a grab), the latter rolls together with the intake shaft, resulting in a mechanical impact on the shaft, which can lead to jamming or destruction of its integrity and, in general, to decrease the reliability of the installation. In the case of placement of the scooping device on a separate additional floating base, capital costs increase.

 When the installation starts, the water-sludge mixture is pumped into the reservoir, as a result of which it becomes turbid, and the technology under consideration is deprived of environmental cleanliness.

 The purpose of the invention is the improvement of consumer properties of the extracted sapropel, ensuring the environmental cleanliness of its production technology, as well as reducing capital costs for the installation, increasing the reliability of its operation and expanding the scope of its use.

 The goal is achieved by the fact that the pumping device is made in the form of a pneumatic blower, the intake part of which is equipped with a grill and placed below the level of sludge in the reservoir, and the working cavity is kinematically connected with a switchgear, which provides alternate communication of the latter with the regions of rarefaction and overpressure of the hydraulic compressor located on the floating base .

 This distinguishing feature provides, firstly, an improvement in the consumer properties of the extracted sapropel due to the fact that the pneumatic blower is a volumetric pumping device. In its working cavity, the sludge moves in the displacement mode, as a result of which there is no intensive mixing and destruction of the natural structure. Secondly, sludge can be mined from any depth without increasing the carrying capacity of the floating base and lifting devices, which leads to lower capital costs for the installation and expands the scope of its use. Thirdly, it is possible to supply sapropel directly to the consumer, located on the shore, under any excess pressure, which depends only on the performance of the hydro-compressor unit, which simplifies the operation of the entire production technology. Fourthly, the pump unit (circulation pump of a hydraulic compressor) runs on clean water, which increases the reliability of the installation. Fifth, the installation does not have any emissions into the environment. Sixth, this distinguishing feature provides the possibility of dosing (packaging) of mined sapropel directly at the place of its extraction. In this case, the dose volume is regulated by the switching frequency of the switchgear and can vary from zero to a value equal to the volume of the working cavity of the pumping device (pneumatic blower).

 The suction pipe of the circulating pump of the hydraulic compressor is partially submerged under the water level in the pond, and the suction pipe of the ejector is connected to the switchgear through a sump.

 This distinguishing feature provides a reduction in energy consumption and an increase in the reliability of the hydraulic compressor, and consequently, of the entire installation. The performance of the hydraulic compressor in compressed air (the performance of the ejector), as well as the maximum vacuum value, depend on the temperature of the working (circulating) fluid that is heated by the pump. On the section of the suction pipe, submerged under the water level in the reservoir, heat transfer occurs and the temperature of the circulating water decreases, which improves the performance of the ejector and reduces the energy consumption for pumping sapropel. The presence of a sump between the suction nozzle of the ejector and the dispenser prevents the possibility of sludge getting into the circulation circuit of the hydraulic compressor, which increases the reliability of its operation.

 In order to further improve the installation, it is equipped with additional, similar to the main distribution and pumping devices, while the outlet pipe of the latter is connected to a similar pipeline of the main one, and the additional distribution device works in antiphase to the main one.

 This distinguishing feature provides equalization of the flow rate of sludge moving along the discharge pipe and increases the productivity of the installation, since the suction cycle in the main air blower coincides in time with the extrusion cycle from the additional one (according to the principle of operation of a multi-cylinder engine).

 In order to further improve the installation, it is additionally equipped with a rigid mount (for example, telescopic) to the floating base of the pumping devices with the possibility of their vertical movement, and their intake parts are equipped with ninety-degree bent inlets whose inlets are turned in the direction of the installation's movement.

 This distinguishing feature makes it possible to extract sapropel from a predetermined depth relative to the surface of the sludge in the reservoir, since the immersion depth of the pumping devices can change during the working movement of the installation. In this case, the trajectory of the transfer of pumping devices will repeat the surface topography of silty sediments.

 Figure 1-3 presents a diagram of the proposed device.

 The device contains a floating base 1 (for example, in the form of a pontoon), a hydrocompressor 2 placed on it. In this case, the suction pipe of the circulating pump of the hydrocompressor is partially submerged under the water level in the reservoir, as a result of which the circulating working water is cooled. A lifting device 3 (for example, a hoist), to which a pumping device 4, made in the form of a pneumatic blower, is attached via a cable, the upper part of the working cavity 5 of which is connected with the regions of rarefaction (suction pipe of the ejector) and overpressure (upper part of the circulation tank of the receiver) through air hose 6 and switchgear 7 (for example, four-way plug valve). Moreover, the latter is connected to the suction pipe of the ejector through a sump 8 and is additionally equipped with a locking device 9. The pumping device is equipped with a discharge pipe 10 in the form of a flexible hose.

 The device (figure 2) further comprises a pumping device 11 and a distribution device 12. In this case, the discharge pipes of the main pumping device 4 and the additional device 11 are combined.

 The device (Fig. 3) further comprises a fastening 13 of the pumping devices to the floating base with the possibility of vertical movement (fastening, for example, can be performed on the principle of a sliding fire ladder). The pumping devices are equipped with sludges 14.

 Installation works as follows.

 Using a lifting device 3, a pumping device 4 with an air hose 6 and a discharge pipe 10 is lowered on a cable under the level of sludge in a reservoir. Turn on the hydraulic compressor 2 and report the suction pipe of its ejector through a switchgear and a valve with atmosphere. In this case, an excess pressure of the air compressed by the ejector is created in the circulation tank-receiver of the hydraulic compressor. Then the valve is closed, and the suction nozzle of the ejector is communicated with the working cavity 5 of the pumping device 4. Under the action of a differential pressure equal to the sum of the hydrostatic pressure in the cavity of the intake device and the vacuum created by the ejector, sludge from the bedding layer enters the working cavity 5. In this case, the lower valve of the pneumatic blower opens, and the upper one closes. At the time of filling the working cavity 5 with sludge, it is communicated with the upper part of the receiver's circulation tank (with the overpressure area) and under the influence of overpressure the sludge is squeezed out into the discharge pipe 10, through which it enters the consumer. In this case, the lower valve of the pneumatic blower closes, and the upper one opens. Then, switching the switchgear is cyclically repeated. At the same time, sludge is supplied to the consumer in portions, the volume of which is equal to the volume of the working cavity 5. In this case, the incoming sludge can be immediately packaged in containers (if it is not required to be dried) and transported over a long distance.

 During the suction period, compressed air in the cavity 5 enters the ejector (the compression pressure is equal to the hydrostatic pressure), which reduces the energy consumption for ensuring the operating pressure of the hydraulic compressor, and additional air consumption from the atmosphere is not required.

 This development method is most rational when the reservoir thickness and sludge humidity are large, and its production can be carried out by the borehole method, which is as follows. The pumping device 4 is deepened (due to self-priming) to the base of the developed layer. When sludge is pumped out, a mine with slopes is formed around it (funnel). Upon reaching the slope value corresponding to the conditions of sludge flow, it begins to move to the pumping device (similar to the process of water reduction). The radius of influence of the pumping device depends on the moisture content of the sludge (its fluidity) and on the depth of the developed layer. In this case, it is possible to conduct development for a long time without moving the installation along the water area of the reservoir.

 During the time of squeezing the sludge from the main air blower, the working cavity of the additional device 11 is in communication with the vacuum region (the suction process is in progress). Then the processes of absorption and extrusion are interchanged. In this case, sludge constantly moves along the discharge pipe 10. To enable metering, each air blower can be equipped with a separate discharge pipe.

The installation moves along the water body of the reservoir at a speed at which the condition V _mouth FQ _mouth is satisfied, where V _{mouth the} speed of the installation; F the cross-sectional area of the inlets of the inlets; Q _mouth installation performance. In this case, the trajectory of the sludge intake can repeat the profile of the surface of the sludge layer. For this, by means of the lifting device 3 and the fastening 13, the immersion depth of the pumping device is changed. This circumstance makes it possible to selectively develop mud deposits.

 PRI me R. The operability of the proposed device was tested on a laboratory bench with the following structural and technological parameters: the height of the working cavity of the pneumatic blower 500 mm; diameter of the working cavity 65 mm; diameter of the discharge pipe 25 mm; valve devices were made with ball valves made of rubber and plastic balls, the inner cavity of which was filled with epoxy resin; hole diameter of the bottom valve 40 mm; hole diameter of the upper valve 25 mm; air hose with an inner diameter of 6 mm.

 As a hydrocompressor, a laboratory setup was used (Fig. 1), with the exception of cooling the circulating water. The Potok electric household pump was used as a circulation pump, and a capacity from a fire extinguisher (10 l) was used as a circulation tank-receiver. The ejector was made of organic glass with a flat flowing part.

The operating overpressure of the hydraulic compressor was 0.1 0.15 MPa. The sapropel of Lake Vishnevskoye, Vyborgsky District, Leningrad Region, was used as the pumped liquid. The moisture content of sapropel was 85%
Switching of the switchgear (four-way valve) was carried out manually.

 Experimental verification showed that the proposed device is operable, simple and reliable in operation. When sapropel was pumped, there was no change in its structure (the fluidity practically did not change compared to the initial state).

 Compared with the prototype of the proposed device has the following advantages.

 The technology for the extraction of sapropel (purification of a reservoir from silty sediments) is absolutely clean from an environmental point of view.

 Using the proposed device can improve the consumer properties of the extracted sapropel.

 Mining can be carried out from any depth without increasing the carrying capacity of the floating base and lifting devices.

 At the place of extraction of sapropel, it can immediately be packaged in containers, since the device can ensure its dosing.

 Simplified operation and increased reliability.

Claims (3)

 1. INSTALLATION FOR PRODUCTION OF LAKE Sludge, containing a floating base, a device for moving along a pond, a lifting device and a pumping device mechanically connected with it, the discharge pipe of which is connected to the consumer, characterized in that the pumping device is made in the form of a pneumatic blower, the intake part of which is equipped grill and is placed below the level of sludge in the reservoir, and the working cavity is pneumatically connected to a switchgear connected to the suction and discharge patras sides of the hydraulic compressor, placed on a floating base, while the circulation pipe of the hydraulic compressor is partially submerged under the water level in the reservoir, and its suction pipe is connected to the switchgear through a sump.  2. Installation according to claim 1, characterized in that it contains additional distribution and pumping devices, while the outlet pipe of the additional pumping device is connected to a similar pipeline of the main one, and the additional distribution device is connected in parallel with the main one. 3. Installation according to claim 2, characterized in that the pumping devices are connected with the floating base with the possibility of vertical movement, and their intake parts are additionally equipped with sluices bent at 90 ^o , the inlet openings of which are deployed in the direction of movement of the installation.

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