SU983183A1 - Apparatus for collecting oil off water surface under ice-forming conditions - Google Patents

Description

The invention relates to hydraulic engineering and can be used to clean the water surface from oil products, in particular cleaning it with floating ice and sludge, as well as collecting floating debris from the surface of the water. ^s

A device for collecting oil is known. from the water surface, including a housing with a guiding apparatus, a vortex chamber, in the lower part of which there is a separator with a shaft — a screw and a screw inside, a drive motor and a device for the selection and pumping of the selected oil into a special container (1 J.

The disadvantage of this device is that _<5 it does not allow high-quality and efficient collection and purification of oil from water in ice conditions, since it cannot collect oil that sticks around the ice, floats between it, and also does not allow to collect oil absorbed into the surface layer of ice.

A device is also known for collecting oil from the surface of water in ice conditions, including a power plant, a guiding apparatus with a guiding channel and a vortex chamber, in the lower part of which there is a separator, a feeding device, under which a grate, a melting chamber and a tank for collecting oil are placed and garbage [2].

A disadvantage of the known device is its inability to carry out work to collect oil from a clogged area.

The purpose of the invention is to increase the efficiency of collection and purification of water and ice from oil and the efficiency of ice melting.

This goal is achieved by the fact that the device is equipped with a pressing chamber having a conical shape, on the front input part of which are made rectangular trapezoidal teeth, connected by the outlet to the melting chamber, mounted obliquely to the horizon and made with hot sprays. water and with a drainage grid dividing the chamber into two zones - liquid, connected * ·

963183 4 flax with a separator, n solid-phase rotary outlet pipe. ''

In addition, the melting chamber is installed inside the heating chamber, which has a supply of exhaust gases ₅ from the power plant of the device.

In this case, the falling device can be made in the form of a screw placed across the guide channel, the outlet part of which is placed in the press chamber, is made with a variable pitch and has teeth in front of it on the external helical surface.

In FIG. 1 schematically shows a device in plan; in FIG. 2 is a section AA in FIG. 1; in FIG. 3 - design of the melting chamber, longitudinal section; in FIG. 4 - node I in FIG. 2.

The device has a hull 1 made in the form of a hull. A guide apparatus 2 is installed in the bow of the body 1, which is integral with the body 1 and consists of two guide channels 3 and two vortex chambers 4 located symmetrically with respect to the central streamlined volumetric wall 5 that divides the guide device 2 into two symmetrical parts. In the lower part of the vortex chamber 4 there is a multi-stage separator 6, inside of which there is a shaft — a screw 7 with a screw 8, driven by a drive motor 9 and mounted on the deck of the hull 1. At the entrance to the guide apparatus 2, transverse to the axis of the guide channels 3 are installed two screws 10, made at the ends with a variable pitch. One of its ends, the screws 10 are attached to the shaft of the gearbox 11 with a drive motor and a streamlined streamlined wall 5 located on the deck, and with its other end, made with a variable pitch, entering the conical pressing chambers 12, which at the same time play the role of a support bearing. The pressing chamber 12 is a Hollow · ⁴⁵ cone, the inner surface of which corresponds to the surface of the end of the screw 10, made with a variable pitch.

'The end surface from the input side of the press chamber 12 is made with a tooth- ⁵⁰ chat. The teeth are made in the shape of a rectangular trapezoid and are turned at a right angle opposite to the direction of rotation of the screw 10. In the cross section, the pressing chamber 12 has grooves — 55 different grooves to prevent rotation of the pressed ice and debris and to ensure its axial movement.

In the vicinity of the entrance to the pressing chamber 12, at the outer ends, along the perimeter of the screw surface of the screw 10, teeth are installed facing the entrance to the pressing chamber 12. The output of the pressing chamber 12 is connected to the melting chamber'D.3, made in the form of a cone expanding to the exit and installed obliquely upwards on the housing 1 of the device. Inside the melting chamber 13, sprayers 14 are installed for supplying hot water, for example spent cooling water from the power plant of the device. A drainage grid 15 is installed along the lower inclined wall of the body of the melting chamber 13, dividing it into two zones - a liquid grid connected to the separator by a pipe 16 and a solid-phase one.

The casing of the melting chamber 13 is installed inside the casing of the heating chamber 17, which has an inlet and an outlet for under—. exhaust gas from a power plant.

At the exit of the melting chamber 13 (solid-phase zone), a rotary pipe 18 is installed so that its exit faces overboard or in a garbage container 19 installed in the housing 1.

On the inner side of the guide channel 3, a grid 20 is installed along the screw 10, which envelopes the screw 10 in a semicircle in the transverse / section and extends along it along the entire width of the guide channel 3 and simultaneously covers the entire passage section of the guide channel 3.

The device comprises a device 21 for collecting and pumping oil into a special container 22 from the funnel 23 of the vortex chamber 4. The device has an air chamber for regulating sediment

24. At the rear of the device there is a mover and a power plant.

When an oil spill occurs under ice conditions, it spills over the surface of the water and is partially absorbed into the pores of the ice surface. Before oil is collected by the device, large ice floes are crushed by an icebreaker. The device, moving with the help of a propulsion device, reaches the oil spill site and turns on the drive motor 9, which, by turning the screw 8, makes water with broken ice and floating oil (indicated by dashed lines) move into the guiding apparatus 2. Step by step guide channel 3, water and oil floating on its surface through

888188 6 it is pushed into the chamber 13 through the rotary pipe 18 overboard, which is previously installed in this position.

The device works equally reliably even in conditions where the surface of the water is clogged with garbage and oil. In this position, the device operates as follows.

the lattice 20 enters the vortex chamber 4, twists, enters the separator 6 and is divided into oil and water components in it, while the water from the separator is removed by screw 8, and the collected oil (indicated by a solid line) in the lower velocity zones is discharged along the separator inner cylinder 6 shne -. lump 7 to the center of the funnel 23 formed inside the vortex chamber, from where, by singing 21, it is discharged into the reservoir 22.

The ice and sludge in this case are crossed out by the grill 20 and the screw 10 are carried away into the pressing chamber 12. The auger is driven into the compression chamber through the gearbox 11, which amplifies the torque, by the drive motor. Large pieces of ice that are not included in the compression chamber 13 are pinched with teeth on the ends of the compression chamber 12 and the screw surface of the screw 10 is crushed _ and enters the compression chamber. The ice, falling into the press chamber 12, is compressed and crushed due to the fact that the screw 10 is made of variable pitch,; where the axial force reaches up to 150 tons, and the press chamber is made in a conical case, it serves as a drying chamber, so shaped. Milled press chamber 12 in the ice falls into the melting chamber 13, preheated vyhlop- _m them gases from a power plant unit, fed into mezhstenoch-. space of the heating 17 and / melting chamber 13.

At the same time, the ice entering the melting chamber 13 is irrigated with hot water supplied, for example, from cooling the device’s power plant through sprayers 14 (the temperature of the outside water at the exit of the internal combustion engine cooling water exchanger is 40-60 ° C). As a result, the ice surface melts under the influence of temperature in the chamber and hot water, turning oil * and water, and, together with the washing hot water, flows through the drainage smelter and enters the vortex chamber 4, the separator 6 and the oil separated therein are discharged into the tank 22 .

Thus, the ice in the melting chamber 13 does not melt completely, but partially, and only the surface layer of ice, in which the oil absorbed into it is located, is washed off. .

Further, ice-free ice from the melting chamber 13, as it arrives

Turn off the supply of hot water to the nozzles 14 of the melting chamber 13, and the rotary pipe 18 is turned 'to the garbage containers 19. Garbage and oil enter the guide apparatus 2 and enter the guide channel 3. The oil flows through. the lattice 20 into the vortex chamber 4 to the separator 6, and the garbage is carried away by the screw 10 into the press chamber 12, where it is pressed under the influence of axial force, as a result of which the absorbed oil and water are pressed, which flows back and through the lattice 20 and enters the separator 6 and from - the garbage squeezed out of the oil enters the melting chamber 13, which in this one is heated externally by the exhaust gases of the power plant.

Large debris (debris, chocks, boxes, etc.) falls between the toothed end surface of the inlet of the press chamber 12 and the toothed ends, the screw surface of the screw 10, gets pinched and crumbles into smaller parts with the teeth and enters the bale chamber 12. As it fills up In the melting chamber 13, the garbage is pushed out through the rotary pipe 18 into the garbage container 19, which is already pre-dried, and is almost ready for use, for example, in burning furnaces and furnaces of energy plants.

The device can change its draft depending on weather conditions (excitement or calm water) using the air chamber 24 by filling it with sea water.

For example, in calm water, oil, settling down, is located on the water surface in a thin uniform layer and in order to minimize the oil-water layer entering the guide channel 3 and being processed in the separator 6, thereby improving the quality of water from oil from the air chamber 24 displace sea water, thereby reducing the draft of the housing 1 and the thickness of the oil layer.

mesh 15 into the lower cavity of the chamber and through the pipe 16 guide: channel 3, where

933183, 8

In case of agitation, on the contrary, the oil is mixed with water and the minimum thickness of the oil-containing layer should be taken equal to the wave height. For this, the air chamber 24 is filled with overboard water 5 and the draft is increased, ensuring that the thickness of the oil-water layer in the guide channel 3 corresponds to the wave height.

Compared with the known installations for the collection of oil from the water surface in ice conditions, the proposed device is universal, it can collect oil both in ice conditions and in conditions when the water surface is cluttered with 5 garbage and makes it possible to clean the latter qualitatively while receiving dried and ready-to-use garbage.

Due to the fact that when collecting oil in jq ice, the ice does not melt completely, but only its surface melts, saturated with oil and water washed off with it (the rest is thrown overboard), energy savings are achieved, 35 the time spent on remelting ice improves the efficiency of use devices. ^ The surface of the water is better cleaned of oil due to the fact that not absorbed into the ice, _{30 is} completely separated.

The design of the device “growth and nA # * is reliable and does not require complex calculations of its main components and parts, while allowing to solve the problem of collecting spilled oil in ice from the surface of water bodies.

Claims (2)

The invention relates to hydraulic engineering and can be applied to the water surface from oil products, in particular, cleaning it with floating ice and sludge, as well as collecting floating debris from the surface of the water. A device for collecting oil from a water surface is known, comprising a housing with a guide vane, a vortex chamber, in the lower part of which a separator with a shaft shaft and screw inside is installed, a drive motor and a device for sampling and pumping the selected oil into a special container C1 3. The disadvantage of this device is that it does not allow to efficiently and effectively collect and clean oil from oxen in ice conditions, as it cannot collect oil that is doused around the ice, floats between it and also does not allow collecting oil embedded in the surface layer of ice. It is also known a device for collecting oil from the surface of water in the ice of the village VSE1X, including a power plant, a guiding device with a guide channel and a vortex chamber, in the lower part of which a separator is placed, a feeding device, under which the grate, the melting chamber and the tank for collecting oil and garbage 2. A disadvantage of the known device is its inability to perform oil gathering operations from a clogged area. The purpose of the invention is to improve the effect of the collection and purification of water and ice from oil and the effectiveness of ice melting. The goal is achieved by the fact that the device is equipped with a pressing chamber having a conical shape, at the front entrance of which there are made trapezoidal bridges connected to the melting chamber set obliquely to the horizon and made with hot sprays water and with a drainage grid separating the chamber into two ashes — liquid, connected to the separator, to solid-phase c. rotary outlet pipe. Kj.iOMe addition, the melting chamber is installed inside the heating chamber, which has an exhaust gas supply of the power installation of the device. In this case, the falling device can be made in the form of an auger placed across the guide channel, the output of which is located in the press chamber, is made in variable pitch and has a tooth before entering it on the outer screw surface. in terms of; in fig. 2 shows a section A A in FIG. 1; FIG. 3 shows the structure of the smelting chamber; longitudinal gap; Fig. 4 shows the assembly 1 in Fig. 2; the Device has a hull 1 made in the form of a ship hull. In the nasal part of body 1, a guide device 2 is installed, integral with housing 1, consisting of two guide channels 3 and two vortex chambers 4 arranged symmetrically with respect to the circular streamlined volume wall 5, separating guide device 2 on two symmetrical parts. In the lower part of the vortex chamber 4 there is a jviHorO stepped separator 6, inside of which is installed the shaft-auger 7 with screw 8, the rotary actuator Dvigate ™ Lem 8 and mounted on the deck of the housing 1, at the entrance to the guide apparatus 2 Two augers 10 are installed across the axis of the passage channels 3, which are made on variable pitch x-pins. At one of their ends, the screws 10 are fastened to the shaft of the gearbox 11 with a drive motor and a volume streamlined wall 5 located on the deck, and with their other END, made in increments of steps, enter the conical press 12 of the chamber 12, which simultaneously performs the role of a supporting sub-holder, The pressing chamber 12 is a yopy-cone, the inner surface of which is coherently corresponds to the surface of the end of the screw 1O, which is made in variable pitch. The end surface on the inlet side of the press chamber 12 is made toothed. The tooth is made according to the shape of a rectangular trapezoid and facing a right angle opposite to the direction of rotation of the screw 1O. In the cross section, the pressing chamber 12 has grooved slots to prevent rotation of the compressed ice and debris and to ensure its axial movement, 5. 4 In the area of the entrance to the pressing chamber 12 at the outer ends, around the perimeter of the screw surface of the screw 10 is installed. The teeth are facing the entrance to the press chamber 12. The exit of the press chamber 12 is connected to the melting chamber J.3, which is wedged in a cone extending to the exit and set obliquely upwards on the body 1 of the device. Inside the melting chamber 13, nozzles 14 are installed to supply hot water, for example spent coolant outboard water, from the power installation of the device. A drainage grid 15 is installed along the lower inclined wall of the melting chamber 13, dividing it into two zones — a liquid one, connected to the separator by a nozzle 16, and a solid-phase one. The casing of the melting chamber 13 is installed inside the casing of the heating chamber 17, having an inlet and an outlet for the sub-. exhaust gas from the power installation of the device. At the exit of the melting chamber 13 (solid-phase zone) there is a rotary nozzle 18, so that its exit is overboard or into the garbage container 19 installed in the root 1, On the inside the guide channel 3 along the screw 10, a grill 20 is installed, enveloping in a semicircle in the cross section (the cross section of the screw 10 and extending along it along the entire width of the guide channel 3 and simultaneously blocking the entire flow section of the guide channel 3, the device contains a device 21 for collecting and transferring oil to a special container 22 from the funnel 23 of the vortex chamber 4, the device has an air chamber 24 for regulating the sludge, there is a propulsion and power installation in the stern of the device.When spilling oil in ice conditions it spills on the surface of the water and is partially absorbed into the pores of the ice surface. Before collecting the oil with the device, large ice floes are crushed by an icebreaker. The device, moving with the help of a double breaker, reaches the place of the oil spill and turns on the driving motor 9, which Screw 8, causes water to move with broken ice and floating light (indicated by dash-dotted lines) in the guiding device 2. Going to the guide channel 3, the water and oil floating on its surface through the lattice 2O enter the vortex chamber 4, swirls, enter separator 6 and kggs section therein into oil and water components, while water from the separator is removed by screw 8, and collecting oil (indicated by a solid line) is withdrawn at lower speeds through the inner cylinder of the separator 6 with a screw 7 to the center of the funnel 23, images The inside of the vortex chamber, from where clause 21 is retracted, is capacitance 22. The ice and sludge are covered by the 2O grating and the screw 10 are carried into the pressing chamber 12, the screw is driven through the gearbox 11, which strengthens the rotational drive motor. Large pieces of ice that are not included in the bale chamber 13 are clamped by means of teeth at the ends of the bale chamber 12 and the screw surface of the screw 10 are crushed and fed into the bale chamber. The ice entering the press, the new chamber 12, is compressed and crushed due to the fact that the screw 10 is made of variable pitch, where the axial force reaches 150 tons, and the pressing chamber is made conical. The ice crushed in the pressing chamber 12 enters the melting chamber 13, which is preheated by exhaust gases from the energy installation of the device, is fed into the interspace of the heating 17 and the melting chamber 13. At the same time, the ice entering the melting chamber 13 is irrigated with hot water supplied, for example, from the cooling of the power plant of the device through the nozzles 14 (the temperature of the outboard water at the internal combustion engine heat exchanger is 10 ~ 60 ° C). As a result, the perpendicular of the ice under the effect of temperature in the chamber and hot water melts, turning into || oil and water, and together with the fresh hot water, flows through the drainage grid 15 into the lower cavity of the melting chamber and through pipe 16 enters the guide: channel 3, from where it enters the vortex chamber 4, the separator 6 and the oil separated therein vessel 22. Thus, ice in the plaza & ilma chamber 13 does not melt by a polygon, but partly and at the same time only the surface layer of ice is washed away, in which the real oil is absorbed into it. . Next, refined from oil avd. From the melting chamber 13 | ON, as it enters the chamber 13, it is pushed over the rotary nozzle 18, which is pre-set to this position. The device works equally reliably in conditions if the surface of the water is clogged with debris and oil. In this position, the device operates as follows. The hot water supply to the sprays 14 of the melting chamber 13 is turned off, and the rotary nozzle 18 is turned to the garbage containers 19. The garbage and oil enter the guiding device 2 and flow into the guide channel 3. Oil flows through. the grid 20 into the vortex chamber 4 to the separator 6, and the garbage is carried by the screw 1O into the pressing chamber 12, where it is pressed under the influence of axial force, which results in squeezing of the absorbed oil and water, which flows back and through the grid 2O and into the separator 6 , and the waste that has been drained from the oil enters the melting chamber 13, which in this case serves as a drying chamber, since it is heated by exhaust gases of the power plant. Coarse debris (debris, chocks, crates, etc.) falls between the toothed end surface of the entrance of the press chamber 12 and the toothed ends, which is 1 cm above the top of auger 1O, is clamped and creased by teeth into smaller parts and enters the bale chamber 12. As the melting chamber 13 is filled, the garbage is pushed out through the rotary nozzle IS. The garbage container 19 is already pre-dried and almost ready for use, such as burning in furnaces and furnaces of power plants. The device can change its draft depending on weather conditions (rough water or calm water) with the help of the air chamber 24 by filling it with seawater. For example, in calm water, the oil settled down is located at the turn of the water flow by taking a uniform layer and in order to minimize to a minimum the freshwater layer entering the guide channel 3 and processed in the separator 6, thereby improving the quality of water from oil from the air chamber 24 discharges the seawater, thereby reducing the draft of the hull 1 in thickness of the oil-water layer. 758316 At rough seas, on the contrary, the oil is mixed with water and the minimum thickness of the oil-bearing layer should be taken equal to the height of the wave. For this, the air chamber 24 is filled with outboard water and the draft is increased, so that the thickness of the oil layer in the control channel 3 corresponded to the height of the wave, Compared to the known installations, to collect oil from the surface water in ice conditions The proposed device is universal, it can collect oil both in ice conditions, and in conditions when the surface of the water is trash-15 lena with garbage and allows you to clean the last one qualitatively, while getting dried and ready for use Due to the fact that collecting oil in 20 odds ice is not melted completely, but only its surface is reflowed, nasptsenna oil and washable together with it water (the rest is discarded overboard), obtained saves energy expended in melted ice and seizing shaets operational use of the device. The surface of the water from the oil is cleared more efficiently due to the fact that the oil that has been absorbed from the ice is completely separated. The structure of the device is simple and it is ny. is reliable and does not require complex calculations os. at the same time, it solves the problem of collecting spilled oil in ice from the surface of a waterborne claim 1, a device for collecting oil from the surface of water in ice conditions, including 35 3 j8 power plant, with a channel and a vortex chamber, in the lower part of which a separator is placed, the feeding device under which the sieve is placed, the melting chamber and the tank for oil and garbage, are different in that in order to improve the efficiency of collection and cleaning water and l From it, it is provided with a pressing chamber having a conical shape, on the front entrance part of which there are rectangular trapezoidal teeth. connected to the exit with a melting chamber installed inclined to the horizon and filled with hot water sprays and with a drainage screen that divides the chamber into two zones - liquid, connected to the separator, and phase-phase with a rotatable outlet. 2. The device according to claim 1, characterized in that, in order to increase the efficiency of ice melting, the melting chamber is installed inside the heating chamber, which has an exhaust gas supply from the power installation of the device ,. 3, the device according to claim 1, characterized in that the yadating device is designed as a screw channel dispersed across the guide channel, the output part of which is housed in the pressing chamber, is made in variable steps and has a front entrance to it on the outer screw surface. , taken into account during the examination 1. USSR auto certificate No. 718537, class, e 02 V 15/04, 1977, 2, US patent no. 4О534О6, class. E O2 B 15 / O4, 1977 ,, 0US.J / 1 - /// To 23 7 8 Fig 2 6 FIG. ъ 12 J5 13