RU2418914C1 - Device to produce silt deposits (versions) - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: device comprises a submerged or a semi-submerged chamber with an intake element, a discharge element and a pump. According to the first version of the device realisation, the chamber is equipped with a vertical partition with a discharge nozzle arranged in it above the chamber bottom. The pump is located in one part of the chamber, and the intake element - in the other part of the chamber. According to the second version of realisation, the chamber is equipped with an additional chamber, which is connected to the main chamber by means of a discharge nozzle arranged above the chamber bottom. The pump is located in the additional chamber, and the intake element - in the main chamber. The intake element according to any of the versions is equipped with an inlet valve and is arranged in the form of a nozzle, one part of which is located outside the chamber. The discharge element is arranged in the form of a discharge pipeline with a check valve connected to the pump.

EFFECT: improved reliability of the device operation due to elimination of pump failures, reduced labour expenditures due to exclusion of additional operations for cleaning of produced sapropel from various fine inclusions and improved quality of the finished product.

14 cl, 4 dwg

Description

The invention relates to the field of extraction of bottom sludge, in particular sapropel from natural reservoirs, and its use, for example, as a fertilizer, filler in the production of building materials, in medicine.

A device for producing sapropel is known, including a pump located in the chamber, a suction pipe and a discharge pipe (RU 2193627 C1, 11.27.2002).

The closest analogue of the claimed invention is a device for the extraction of silt deposits, including a chamber with a sampling element, a discharge element, a pump (RU 2030518 C1, 03/10/1995).

A disadvantage of the known devices is the unreliability of the device due to the possible ingress of various inclusions of silt deposits into the pump, as well as the need for additional purification of the extracted sapropel for its subsequent use.

The objective of the claimed invention is to remedy these disadvantages.

The technical result is an increase in the reliability of the device due to the elimination of pump failures, reduction of labor costs due to exclusion, additional operations to clean the extracted sapropel from various small inclusions from silty deposits and to improve the quality of the resulting product (sapropel).

This is achieved by the fact that, according to the first embodiment, in the device for the extraction of silt deposits, including a chamber, a sampling element, a discharge element, according to the invention, the device is equipped with a pump placed in the chamber, and the chamber is equipped with a vertical partition with an unloading pipe located above it on the bottom of the chamber, the pump is located in one part of the chamber, and the intake element in the other part of the chamber, is equipped with an inlet valve and is made in the form of a pipe, one part of which is located outside the chamber, and the discharge element nt configured as a pump connected to a discharge pipe with a check valve.

According to a second embodiment, in a device for the extraction of sludge, including a chamber with a suction element, a discharge element, according to the invention, the device is equipped with a pump and the camera is equipped with an additional chamber connected to the main chamber by means of an unloading pipe located above the bottom of the chamber, while the pump is located in an additional the chamber, and the intake element in the main chamber, is equipped with an inlet valve and is made in the form of a pipe, one part of which is located outside the chamber, and the outlet element made in the form of a pressure pipe connected to the pump with a check valve.

In addition, in each of the embodiments of the device, the discharge pipe is equipped with a mesh filter. The intake element is equipped with a bucket located in front of the end of the intake element located outside the camera in the direction of movement of the device. The bottom and walls of the chamber or the main and secondary chambers have inspection hatches. When executing a submersible chamber, a part of the chamber with a pump located in it or the main and additional chambers are connected to the atmosphere through pipes. When the chamber is semi-submersible, each part of the chamber or the main and additional chambers are made in the form of pipes of round or square cross section, the upper end of which is located above the surface of the water. The bottom of the chamber with the intake element or the main chamber is made in the form of a sealed cover.

The invention is illustrated by drawings, where

on figa, b shows an embodiment of a device with a submersible chamber divided by a partition;

figure 2 shows an embodiment of a device with a submersible main and semi-submersible additional cameras;

figure 3 shows an embodiment of the semi-submersible with the primary and secondary cameras.

The device comprises a chamber 1 with an intake 2 element, an outlet 3 element, a pump 4. According to the first embodiment of the device (Fig. 1), the chamber 1 is provided with a vertical partition 5 with an unloading nozzle 7 located above it on the bottom 6 of the chamber 1. The pump 4 is located in one part of the chamber 1, and the intake element 2 in the other part of the chamber 1. According to the second embodiment of the device (Fig. 2), the chamber 1 is provided with an additional 8 chamber connected to the main chamber via the discharge chamber 7 located above the bottom 6 of the main chamber 1. Pump 4 is located in the additional 8 chamber, and the intake 2 element is located in the main chamber 1. In this case, both in the first (Fig. 1b) and in the second embodiments of the chamber 1, the intake 2 element is equipped with an inlet valve 9 and is made in the form of a pipe, one part of which is located outside the camera. The outlet 3 element is made in the form of a pressure pipe connected to the pump 4 with a check valve 10. The discharge pipe 7 is equipped with a filter mesh 11 to prevent various small inclusions from entering the pump 4, which eliminates its breakdown and, therefore, increases the reliability of the device. In addition, the product supplied to the outlet 3 element does not need further purification, i.e. labor costs are reduced and the quality of the resulting product is improved. The fence 2 element can be equipped with a bucket 12 located in front of the end of the fence 2 element located outside the camera in the direction of movement of the device. The bottom 6 and the walls of the chamber 1 with a partition 5 or the main 1 and an additional 8 chambers have inspection hatches. When the camera is immersed, each part of the chamber 1 or the main 1 and additional 8 chambers are connected with the atmosphere through pipes 13. When the camera is executed, the semi-submersible part of the chamber 1 with the pump 4 located in it (Fig. 2) or the main 1 and additional 8 chambers are made in the form a semi-submersible pipe of circular or square cross section, the upper end of which 14 is located above the surface of the water. The bottom 6 of the chamber with the intake 2 element or the main 1 of the camera is made in the form of a sealed cover. Due to the location of the discharge pipe 7 above the bottom 6, a settler 16 is formed in the chamber, in which large inclusions present in the developed silts settle (stones, lumps, pebbles, gravel, etc.)

Intaking 2 element can be made flexible in the form of a pipe.

Pump 4 can be centrifugal, screw, screw, piston, diaphragm, peristaltic and is selected taking into account the viscosity and density of the developed rock, the depth of development, the length and diameter of the pressure pipe, the height of the discharge point above the water level.

The feed pump 4 can be equipped with both electric and hydraulic drive (motor). For the reliability of the pump 4, the connection of the motor with the pump shaft, as well as the exclusion of engine oil from entering the reservoir, pump 4 is placed in the part of the chamber separated by a partition 5 or in an additional chamber 8.

The inlet valve 9 can be placed outside the chamber 1 in front of the lower point of the intake element 2 (Fig. 1b, Fig. 2) or inside the chamber (Fig. 1a). The option of placing the valve 9 outside the chamber 1 facilitates the control of the valve 9, but increases the pressure loss at the inlet. This option of placing the valve 9 is applicable when working at great depths, and the option of intracameral placement of the valve 9 is acceptable when working at shallow depths.

The device operates as follows.

Before starting work, the valve 9 is closed and the device is immersed in the thickness of the developed, for example, sapropel to the depth of development, so that the lower plane of the bucket 12 is above the boundary of the viscoplastic state of the clay layer so that the clay layer in the viscous-fluid state is above the bucket 12 and it is possible pulling it into the bucket due to external hydrostatic pressure. The rock is drawn into the submersible or semi-submersible chamber 1 through the bucket 12 and intake element 2 due to the external hydrostatic pressure that occurs when the chamber 1 is immersed. The sapropel is pulled into the chamber 1 due to the pressure drop inside and outside the chamber 1, because the pressure outside the chamber 1 is P _n = γh, where h is the immersion depth of the chamber 1 (immersion depth of the upper point of the intake element 2), and the pressure inside the chamber corresponds to atmospheric. The greater h, the greater the pressure outside the chamber 1, the higher the retracting ability of the device. At large depths of development, the speed of retraction of sapropel into the chamber 1 through the bucket 12 and the intake 2 element can be controlled by the resistance of the valve 9.

After filling the part of the chamber with the intake 2 element or the main chamber 1, they are emptied through the discharge pipe 7, connected to the part of the chamber, in which the pump 4 is located or with the additional chamber 8 with the pump 4. The feed pump 4 makes the fence (retraction) of the rock from the part chambers with a sampling 2 element or their main chamber 1 due to a small back-up of rock arising in the chamber part with a sampling 2 element or from the main chamber 1 and due to the discharge created by the pump 4 at the pump inlet, and the rock feed into the discharge The 3rd element in the form of a pressure pipe carries out due to the pressure created by the pump 4 at the pump outlet.

By adjusting the capacity of pump 4 in accordance with the filling rate of chamber 1, it is possible to achieve a balance between the volume of sapropel being drawn into chamber 1 and the volume of pumping sapropel by pump 4. Moreover, the lower the viscosity of sapropel and the greater the depth of development, the higher the productivity of pump 4.

The outlet 3 element in the form of a pressure pipe, equipped with a check valve 10, ensures the exclusion of the backflow of sapropel from the pressure pipe to the pump 4, in case it stops, rises and repairs the device.

For operational maintenance of chambers 1 and 8, the bottom 6 and the walls of the chambers can be equipped with hermetic inspection hatches, allowing, for example, to inspect the chambers, clean the sump 16 from large accumulations, check the working condition of pump units 4, connecting cables (with the electric version) and hydraulic hoses (with hydraulic version).

Due to the fact that pump 4 does not have to work directly to draw in the sludge, as the structure of the sludge is broken when it enters the chamber 1, the pump 4 draws fluid rock with a broken structural lattice under a small backwater from the chamber 1 through the discharge element, which greatly facilitates the working conditions of the pump and allows it to provide the necessary power only for feeding the rock into the pressure pipe.

Claims (14)

1. A device for the extraction of silt deposits, including a chamber, a sampling element, a discharge element, characterized in that the device is equipped with a pump placed in the chamber, and the chamber is equipped with a vertical partition with an unloading pipe located above it on the bottom of the chamber, while the pump is located in one parts of the chamber, and the intake element in another part of the chamber, is equipped with an inlet valve and is made in the form of a pipe, one part of which is located outside the chamber, and the outlet element is made in the form of a pressure pipe connected to the pump piping with check valve. 2. The device according to claim 1, characterized in that the discharge pipe is equipped with a mesh filter. 3. The device according to claim 1, characterized in that the intake element is equipped with a bucket located in front of the end of the intake element located outside the camera in the direction of movement of the device. 4. The device according to claim 1, characterized in that the bottom and walls of the chamber have inspection hatches. 5. The device according to claim 1, characterized in that when the immersion chamber is executed, each part of the chamber is in communication with the atmosphere through pipes. 6. The device according to claim 1, characterized in that the chamber is made semi-submersible, while part of the chamber with the pump located in it is made in the form of a pipe of circular or square cross section, the upper end of which is located above the surface of the water. 7. The device according to claim 1, characterized in that the bottom of the chamber with the intake element is made in the form of a sealed cover. 8. A device for the extraction of silty sediments, including a chamber with a suction element, a discharge element, characterized in that the device is equipped with a pump, and the camera is equipped with an additional chamber connected to the main chamber through the discharge chamber located above the bottom of the chamber, while the pump is located in the additional chamber and the intake element is in the main chamber, is equipped with an inlet valve and is made in the form of a pipe, one part of which is located outside the chamber, and the outlet element is made in the form of a pump connected pressure pipe with a check valve. 9. The device according to claim 8, characterized in that the discharge pipe is equipped with a mesh filter. 10. The device according to claim 8, characterized in that the intake element is equipped with a bucket located in front of the end of the intake element located outside the camera in the direction of movement of the device. 11. The device according to claim 8, characterized in that the bottom and walls of the main and additional cameras have inspection hatches. 12. The device according to claim 8, characterized in that the main and secondary chambers are immersed, while the main and additional chambers are in communication with the atmosphere through pipes. 13. The device according to claim 8, characterized in that the primary and secondary chambers are made semi-submersible, while the primary and secondary chambers are made in the form of pipes of circular or square cross section, the upper end of which is located above the surface of the water. 14. The device according to claim 8, characterized in that the bottom of the main chamber is made in the form of a sealed cover.

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