RU2390612C2 - Drag head of hydraulic dredge - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to hydraulic mechanisation, in particular to technical means for production of minerals from under water. Drag head of hydraulic dredge includes tip with suction mouth, pipe of water supply and hydraulic giant. Hydraulic giant is equipped with nozzles for transportation of soil, which are directed towards tip. Nozzles for transportation of soil are equipped with additional nozzles for soil rippling, which are installed with the possibility to develop zone of ripped soil around the main nozzles.

EFFECT: improved efficiency of operation in development of tight compressed soils.

5 cl, 19 dwg

Description

The present invention relates to hydromechanization, in particular to technical means of extracting minerals from under water.

A suction device for an dredging projectile is known, including a suction tip and a collector with nozzles, while the suction tip is divided by a collector with nozzles in height into two separate suction sections (AS USSR No. 1208145, E02F 3/88, 1984). Known soil intake device allows you to conduct soil development at various depths. A disadvantage of the known device is the low consistency of the soil, since a large amount of clean water is sucked along the perimeter of the tip when sucking in soil washed out with a hydraulic ripper. This reduces the efficiency of the device. In addition, since the soil is taken through a narrow gap between the tip and the soil in the conditions of a small active suction zone, the soil sampling mode is constantly changing due to changes in the soil properties, the height of its slope, the speed of the device, etc., which reduces productivity soil intake. Soil cultivation is carried out by the erosion method, characterized by a small area of active cultivation. It also reduces the stability of the soil sampling process, and when the slopes of the soil collapse, the tip gets slaughtered and the work stops.

Also known is a suction device for an dredging projectile, including a suction tip with an adjacent water supply channel with an element for regulating the flow area and a hydraulic ripper, while the lower part of the separation wall between the suction tip and the water supply channel is made in the form of one or more plates mounted for movement along the separation walls (AS USSR No. 1155688, E02F 3/88, 1982). In this soil sampling device, the process of loosening the soil is supposed to be carried out by the diffusion method, which increases the consistency of the water-soil mixture. However, soil sampling is also carried out by suction through a narrow gap. Moreover, the size of the suction gap can be controlled not only by moving the tip, but also by changing the position of the plates mounted on the dividing wall between the suction tip and the water supply channel, which increases the stability of the soil in comparison with the previous technical solution. However, the active suction zone also remains small, therefore many factors have a great influence on the stability of the soil sampling process, which reduces productivity. In addition, it is necessary to note the complexity of the working movements of the soil sampling device, since it is designed to work only under a layer of soil. In the presence of associated underlying layers, the operation of the device is generally excluded.

Also known is a suction device for a dredging projectile, including a tip with a suction pharynx, a water supply pipe and a hydraulic monitor for loosening the soil (Papulov V.I., Menshchikov A.I., Ivanov A.S. Development of underwater mineral deposits. - M .: CPU NTGO, MGI, 1983, p. 12, Fig. 4.1g). Soil loosening can be carried out by a hydraulic monitor both by the erosion method and by the diffusion method due to the possibility of axial movement of the hydraulic monitor, which slightly increases the consistency of the water-soil mixture. However, soil sampling is also carried out only by absorption through a narrow gap, therefore, the active absorption zone remains small, which excludes the stability of the soil sampling and reduces its productivity.

A suction head is known to be a sucker, including a suction pipe with a pharynx and a screen, hydraulic monitor nozzles located along the axis of the pipe, the screen being made in the form of a box facing the open chest to the bottom of the face, and the nozzles are mounted in rows along lines perpendicular to the axis of the suction pipe, and sent to his pharynx (USSR AS No. 291001, E02F 3/88 of 06/05/1969). Thanks to the installation of L-shaped nozzles along the axis of the pipeline, the suction zone increases, which stabilizes the soil sampling process. However, the location of the hydraulic nozzles at the bottom of the suction pipe leads to the location of the suction pharynx at the bottom of the face, which causes the soil to rotate 180 ° from the movement communicated to it by the nozzles. This increases the energy consumption for absorption and leads to a decrease in the consistency of the sucked-in water-soil mixture and the productivity of the dredger. In addition, with this arrangement, the nozzles transport the soil down to the bottom of the bottom, and then with the help of a soil pump, the soil again rises up the suction pipe, which is also associated with additional energy costs and a decrease in the consistency of the sucked-in water-soil mixture and the capacity of the dredger. Therefore, to ensure the efficient operation of the suction head of the sucker, it is necessary that the nozzles are located outside the suction pipe. It should also be noted that the L-shaped nozzles are effective for hydrotransporting the soil, but, as experience has shown, are ineffective for hydraulic loosening, which reduces the depth and volume of loosened soil, especially caked soil. Therefore, when moving the suction head of the pine to the side of the bottom of the face, the L-shaped nozzles abut against the bed of soil and reduce the amount of soil transported, which reduces the consistency of the sucked-in water-ground mixture and productivity on the ground.

It is known and adopted as a prototype a dredger suction device, including a tip with a suction pharynx, a water supply pipe, a hydraulic monitor for loosening the soil, equipped with nozzles for transporting soil directed towards the tip (RF Patent Utility Model No. 47394 E02F 3/88, 3/92 dated March 16, 2005). In a known technical solution, in comparison with the aforementioned, the hydraulic monitor with nozzles is moved outside the suction pipe, due to which the suction pharynx is located in the upper part of the developed soil mass and the nozzles transport the soil from bottom to top from the bottom of the face to the suction pharynx in the direction of suction without turning it 180 ° , which reduces the energy of the soil pump for suction and increases the consistency of the sucked-in water-ground mixture. However, in the known soil sampling device, as in the technical solution discussed above, both hydraulic loosening of the soil and its transportation are carried out by L-shaped nozzles, which are effective for hydrotransporting and loosening light non-trailed soils. The operating experience of known soil sampling devices in the development of dense compacted soils has shown their low efficiency due to the low loosening ability of the jets from L-shaped nozzles that interact tangentially with the soil surface. When moving a monitor with nozzles in the process of soil sampling, the L-shaped nozzles abut against the ground, which reduces the speed of movement of the monitor with the soil receiver in the soil thickness and the efficiency of the soil sampling. At the same time, the depth and volume of loosened soil are reduced, which reduces the consistency of the sucked-in water-soil mixture and the productivity on the soil. When sampling high-density soils, work is often impossible.

Solved by the invention, the task is to increase work efficiency in the development of dense compacted soils.

The technical result that can be obtained using the proposed technical solution is the creation of a zone of previously loosened soil around the conveying nozzles.

To solve the problem with the achievement of the specified technical result in a well-known suction device of an dredging projectile, including a tip with a suction pharynx, a water supply pipe, a hydraulic monitor equipped with nozzles for transporting soil, according to the invention, nozzles for transporting soil are equipped with additional nozzles for loosening the soil, installed with the possibility of creating a zone of loosened soil around the main nozzles.

Additional options for the dredging device of the dredging projectile are possible, in which it is advisable that:

- additional nozzles were installed on the periphery of the core;

- additional nozzles were installed ahead of the main ones in the direction of the monitor;

- the axis of the additional nozzles were installed in the same plane with the axes of the main;

- additional nozzles were equipped with knives for mechanical cutting of soil, mounted in front of the nozzles in the direction of the monitor.

The indicated advantages, as well as the features of the present invention are illustrated by the variants of its implementation with reference to the drawings: Fig. 1 shows a side view of a device with a hydraulic monitor; figure 2 is a view of figure 1; figure 3 is a section bB in figure 1; figure 4 is a cross-section bb in figure 1; figure 5 is a cross section GG in figure 1; figure 6 - section DD in figure 4; Fig.7 is a section EE in Fig.5; on Fig shows a side view of the device with additional nozzles mounted in front of the main in the direction of the monitor (to the right); Fig.9 is a view of G in Fig.8; figure 10 is a view G in figure 8 (option with two monitors); figure 11 is a section II in figure 8; on Fig - section KK on Fig; on Fig - section LL in Fig; in Fig.14 - section II in Fig.1 (option with two monitors); on Fig - section KK on Fig (variant with two monitors); in Fig.16 - section MM in Fig.11 and 14; on Fig - section HH in Fig.12 and 15; on Fig - section PP in Fig; on Fig - section TT in Fig.17.

The soil intake device of the dredging projectile includes a tip 1 with a suction pharynx 2, a water supply pipe 3 and a hydraulic monitor 4. The hydraulic monitor 4 is equipped with nozzles 5 for transporting soil, as well as additional nozzles 6 for loosening the soil. At the end of the hydraulic monitor 4, a nozzle 7 is installed for loosening the foot of the slope. A screen 8 is installed above the pharynx 2, which reduces the absorption of pure water into the pharynx. The screen is connected by stiffness beams 9, 10, 11 with a monitor 4 and a tip 1 with the formation of a spatial rigid truss that increases the strength of the soil sampling device. The soil intake device can be equipped with one monitor 4 with nozzles (Fig. 1, 2, 3, 4, 5, 9, 11, 12, 13), with two monitors (Fig. 10, 14, 15) and more monitors, depending on the width of the suction pharynx 2 of the soil receiver 1. To ensure a stable installation of the nozzles 5, ribs 12 are provided on the monitor 4. The nozzles can be equipped with knives 13 for mechanical cutting of the soil. The soil receiver 1 is connected to the suction pipe 14.

Dredging device dredger works as follows. Before starting work, water is supplied through a pipe 3 to the hydraulic monitor 4 from the pump of a hydraulic cultivator (not shown). Then the tip 1 is lowered to a predetermined depth of development and the dirt pump (not shown) is turned on. During operation, the soil sampling device is lowered downward, while the hydraulic monitor 4 is introduced into the soil due to the erosive effect of water flowing out of the nozzles 6 and 7. The washed out soil is displaced by the water coming again from nozzles 6 and 7, is picked up by water jets flowing from the nozzles 5, and transported by them further to the suction pharynx 2. The nozzles 5 are installed along the hydraulic monitor 4 and provide soil transportation along its entire length to the suction pharynx 2. Through pharynx 2 soil enters the tip 1 and then through the suction pipe is transported to the soil pump.

During the pit operation, the soil pick-up device is lowered. The water monitor and nozzles also fall down, while the jet of water from the nozzles 6 act on the bed of soil and erode it. The soil is mixed with water flowing from the nozzles 6, with the formation of a zone of highly saturated water-soil mixture. When lowering the soil intake device after the nozzles 6 mounted on the periphery of the nozzles 5 (Figs. 1-7), nozzles 5 enter the loosened soil zone. Water jets flowing from the nozzles 5 pick up the soil washed out by the nozzles 6 and move it to the suction pharynx. At the same time, water from nozzles 6 acts on the soil at a right angle, which ensures high efficiency of loosening of packed dense soils, and nozzles 5 only transport soil. Thus, the supply of nozzles 5 with additional nozzles 6 makes it possible to separate the erosion and transportation functions that previously only performed nozzles 5, between them, taking into account their effectiveness: nozzles 6 are loosened and the soil is prepared for transportation, nozzles 5 are transported. Therefore, due to the installation of nozzles 6 on the periphery of the nozzles 5, efficient pit operation is ensured in the development of dense compacted soils.

When working with the pit-trench method, the soil pick-up device not only lowers down, but also moves forward (to the right in Fig. 8). The water leaking out from nozzles 6 and 7 with water jets loosens up: the soil separated from the bottom bed is mixed with water flowing out from nozzles 6 to form a zone of a highly saturated water-ground mixture. When moving the soil intake device after the nozzles 6 installed in front of the nozzles 5 in the direction of the monitor (Figs. 8-19), nozzles 5 enter the area of the loosened soil. The jets of water flowing from the nozzles 5 pick up the soil washed out by the nozzles 6 and 7 and move it to the suction pharynx. At the same time, water from nozzles 6 acts on the soil at a right angle, which ensures high efficiency of loosening of packed dense soils, and nozzles 5 only transport soil. Therefore, thanks to the installation of nozzles 6 in front of the nozzles 5 along the direction of movement of the monitor, efficient pit-trench operation is ensured when developing dense, compacted soils.

Thus, when using the pit and pit-trench methods, additional nozzles 6 create a zone of loosened soil around the nozzles 5, which ensures effective loosening of the nozzles 6 and efficient transportation of the soil by nozzles 5, so that the soil is taken with high saturation of the water-ground mixture. Choosing the optimal ratio of the diameters d ₅ and d ₆ , depending on the type of soil and operating conditions, the maximum productivity of the soil sampling device is achieved.

Due to the large length of the loosening zone (suspended soil) when installing nozzles 6 along the hydraulic monitor 4, large inclusions (for example, cobblestones) that fall will fall down in this zone and will not fall into the mouth 2. This will reduce the time spent on cleaning the soil pipe, which will also increase operational productivity dredger.

In the event of a sudden collapse of the soil arch above the soil receiver, its blockages are excluded, since the soil will be actively eroded by jets from nozzles 6, 7 and 5 and transported to the pharynx 2 in the form of a water-soil mixture, excluding disruption of the soil intake and stopping of the dredger to free the soil receiver from the blockage.

The installation of the axes of the additional nozzles 6 in the same plane with the axes of the nozzles 5 ensures the creation of a zone of loosened soil directly in front of the nozzles 5, which facilitates the movement of the monitor 4 in the thickness of the soil and thereby increases the consistency of the sucked-in water-soil mixture.

The radial installation of the nozzles 6 provides loosening of the soil around the monitor 4 at a maximum distance, creating the maximum amount of loosened soil at a given flow rate through the nozzle 6, which expands the area of loosening of the soil.

The installation of knives 13 in front of the nozzles 6 will ensure the cutting of particularly dense layers of soil.

Claims (5)

1. The soil intake device of the dredging projectile, including a tip with a suction pharynx, a water supply pipe and a hydraulic monitor equipped with nozzles for transporting soil directed towards the tip, characterized in that the nozzles for transporting soil are equipped with additional nozzles for loosening the soil, installed with the possibility of creating a zone loosened soil around the main nozzles. 2. The intake device of the dredger projectile according to claim 1, characterized in that the additional nozzles are installed on the periphery of the main ones. 3. The intake device of the dredger projectile according to claim 1, characterized in that the additional nozzles are installed in front of the main ones in the direction of movement of the monitor. 4. The intake device of the dredger projectile according to claim 1, characterized in that the axes of the additional nozzles are installed in the same plane with the axes of the main ones. 5. The intake device of the dredger projectile according to claim 3, characterized in that the additional nozzles are equipped with knives for mechanical cutting of the soil mounted in front of the nozzles in the direction of movement of the monitor.

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