RU25176U1 - DEVICE FOR CLEANING RESERVOIRS FROM VISCOUS OIL DEPOSITS AND VISCOUS DEPOSITS OF OIL PRODUCTS - Google Patents

Description

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SHCHShShShShRYRYASHA MPK7V08V9 / 08 Device for cleaning tanks from viscous oil deposits and viscous deposits of oil products

The utility model is intended for cleaning the internal cavity of reservoirs, as well as the internal surfaces of reservoirs of all sizes, from viscous oil deposits and viscous deposits of oil products.

A known method of cleaning tanks from oil deposits, including liquefaction, heating, moving and mixing oil deposits and removal and transportation of liquefied deposits, is described in patent RU 2109583, class. B08B 9/08, 04/27/1998. The known method is characterized by insufficient cleaning efficiency.

The above information source also describes a device for cleaning reservoirs of oil deposits, comprising a device for heating deposits, means for diluting oil deposits, means for moving and mixing the deposits, and means for removing and transporting the liquefied deposits.

A disadvantage of the known device is the design complexity.

The proposed solution eliminates the above disadvantages of the closest analogue.

The technical result of the utility model is the improvement of its design.

By mixing the sediments is meant the movement of the liquefied layers relative to each other, and by moving the delivery of the deposits inside the tank to the location of the structural elements of the tank through which the liquefied deposits are pumped.

metal and mechanical impurities weighing up to 50 volume percent, and viscous deposits of petroleum products include mechanical impurities of a greater mass than the above, while the content of other impurities in these deposits (paraffin and asphaltene fractions, etc.) is lower than in the above.

The objective of this utility model is to clean the reservoir cavity from both one and the other named deposits.

This problem is also solved by the fact that in a device for cleaning reservoirs of viscous oil deposits and viscous deposits of oil products, containing means for heating and liquefying oil deposits, as well as for moving and mixing deposits, including ejector means and means for draining and transporting liquefied deposits, the monitor consists of a hollow rod designed to be fed through it into the working medium reservoir in the form of water vapor or gas, or liquid. A fixing device, for example, a crosspiece, is installed in the upper part of the rod, and the lower part of the rod is connected to at least one ejector head made in the form of a nozzle with a diffuser nozzle for sucking in, heating, diluting, homogenizing deposits and moving liquefied deposits, moreover, at least one ejector head, if there are several, is directed at an angle to the horizontal, i.e. a plane perpendicular to the axis of the rod.

The axis of at least one ejector head crosses or does not cross the axis of the rod.

In one embodiment of the above device, the monitor may comprise a pair of ejector heads, each of which is rigidly fixed to the rod at an angle to the horizontal.

In another embodiment, the monitor contains two pairs of ejector heads, rigidly fixed to the rod and located at the same level at an angle to each other. , in the next version, the monitor contains two pairs of ejector heads, rigidly fixed on the rod and located at different levels at an angle to each other, while the monitor is made to rotate relative to the axis of the rod, and the ejector heads are rotatable relative to the rod. The monitor can be made in the form of a steam, pneumatic or hydraulic monitor, and its nozzle, if several of them can have different sections. The monitor rod is made with the possibility of axial movement relative to the mounting cross and fixing on it in the selected position and may consist of several parts for changing its length. Means for the removal and transportation of liquefied sediments is made in the form of at least one pipeline and pump or installation obtained by sequentially aggregating (connecting) several pumps of any standard size. In addition, the device, if necessary, can be equipped with means for introducing water to ensure separation of deposits, as well as means for cleaning the inner surface of the tank. Figure 1 shows a General view of the device for cleaning with multiple ejector heads; figure 2 is a view along arrow a in figure 1; in Fig.3 is a view along arrow B in Fig.1. A device for cleaning reservoirs of viscous oil deposits and viscous deposits of oil products in one embodiment includes means for liquefying oil deposits, for heating, for moving and mixing sediments, and means for removing and transporting liquefied deposits. Means for heating, liquefying deposits are steam monitors, pneumomonitors or hydraulic monitors (Fig. 1) with ejector heads 1 mounted on a hollow rod 2 at any 1 angles to it and to each other and made in the form of nozzles 3 (Fig. 3) of various cross-sections for supplying a working fluid equipped with confuser-diffuser nozzles 4 for sucking, heating, liquefying, homogenizing deposits and moving liquefied deposits, at least one ejector head directed at an angle to the horizontal (Fig. 1). As can be seen from figure 1, one pair of ejector heads with nozzles 3 located, for example, from above, is located in one horizontal plane and is designed to heat and move the volume of deposits, and another pair, located, for example, from below, provides rotation of the monitor relative to it the vertical axis when applying to its nozzle the working fluid in the form, for example, of water vapor. The specified rotation is due to the curved shape of the nozzles 3, which are pairwise oriented in opposite directions (Fig.Z). In the upper part of the rod 2, a mounting device is installed in the form of a mounting crosspiece 5 (figure 2), which allows you to mount the monitor on the flanges of tank hatches having different diameters. In addition, the crosspiece is made with the possibility of axial movement relative to the rod and is fixed on it by means of the element 6 (figure 1). Pneumatic, steam and hydraulic monitors are equipped with mechanisms for their rotation relative to the vertical forming rod (not shown). The device is also equipped with pumps of any standard size or plants obtained by sequentially aggregating (combining) such pumps for the removal and transportation of liquefied sediments. In addition, the device, if necessary, can be equipped with means for introducing water, designed to ensure separation of sediments, as well as means for cleaning the inner surface of the tank after removal of sediment from it.

The device operates as follows.

The sediment is heated and moved and / or stirred using monitors, which are a hollow rod 2 and attached to it at any angles (depending on application conditions) relative to each other and the rod itself, ejector heads 1, which consist of nozzles 3 through which the working a body in the form of water vapor, gas, liquid under pressure, equipped with confuser-diffuser nozzles, providing suction and movement of the liquefied sediment.

Monitors can be made in any configuration, any size, device and composition. In addition, they can be equipped with rotation mechanisms of any type (including lockable ones) of the monitor itself with respect to the vertical forming rod, as well as mechanisms of any type (including lockable ones) that ensure rotation of the ejector heads relative to the rod itself. Monitors should have at least one ejector head not horizontally directed. To ensure separation of the liquefied sediments into a hydrocarbon fraction and solids, water may be added to the reservoir. Mixed, liquefied and separated in such a way deposits are removed from the reservoir through its structural elements using vacuum, diaphragm, screw (sediagonal), centrifugal, cantilever, gear, piston pumps of any standard size (depending on conditions and tasks) or installations obtained in series connection (aggregation) of such pumps. Deposits are removed to another tank, process pipe, sump, filter, separator (including a centrifuge or decanter). After removing these deposits from the tank, depending on the conditions and tasks, cleaning of its internal surfaces may be carried out. Cleaning can be carried out using a steam jet of any saturation, with a temperature of 95 to 250 ° C and a pressure of 0.1 to 1000 atmospheres; or a water jet with a temperature of 0 to 100 ° C and a pressure of 0.1 to 1000 atmospheres; either by sandblasting or shot blasting of any type with any type of drive; or using any possible combinations. Examples of the use of a pneumo- or hydraulic evacuator Example 1. Steel vertical tank without nonton. Hatches are opened on the roof of the tank, through which monitors with ejector heads are introduced into the tank. The monitors are designed in such a way that in the upper part of the rod there is a universal mounting crosspiece that allows the monitor to be mounted to flanges of hatches of any diameter found on tanks of this type, and also allowing the rod to be moved in the vertical direction relative to the crosspiece itself. The rod can be fixed at any point relative to the crosspiece with a special clamp of a larger diameter than the internal diameter of the opening of the crosspiece. The rod consists of parts equipped with fittings for increasing (or shortening) its length depending on the need (height of a particular tank, etc.). A monitor with two non-horizontal, oppositely directed, rigidly fixed (or blocked) ejector heads. Mostly used when the level of sediment in the tank does not exceed 0.5 meters. A feature of tanks without a pontoon is the minimum number of structures inside the tank that impede the flow of heated sediment, organized by the operation of the monitor. Therefore, in this case, the most effective is the use of monitors with fixed heads, because this allows you to control and adjust the direction of flow by rotating the monitor around the axis of the rod. In addition, such a monitor consumes less steam for operation compared to other types of monitors, which allows for the same amount of steam at the disposal of the work producer to cover a large area of sludge treatment by increasing the total number of monitors mounted on reservoir. A monitor can be used with two pairs of heads located at the same level at angles to each other, when the heads are rigidly fixed and at least one of them is not directed horizontally (which allows creating a stream of heated sediment at an angle to the horizontal generatrix, ensuring that the best heat transfer between sediment layers). Such monitors are mainly installed near large internal reservoir structures (erosion system, popping, etc.), which allows you to wash out sediment from under the structures, heating the maximum possible area on the bottom. It can also use a monitor with two pairs of heads, pairwise located at different levels, rigidly fixed (or locked) on the bar and pairwise directed at angles to each other, while one pair is not directed horizontally. It is mainly used in tanks with a high level of sediment (more than 0.5 meters) in order to uniformly heat and move the sediment throughout the thickness of the layer. On tanks of this type, but of small diameter (up to 40 meters), monitors of all the above options can also be used, but equipped with rotation mechanisms: like ejectors relative to the boom - at a high level of sediment, providing heating and mixing of the sediment with the installation of one such monitor in the center of the tank , and the entire structure relative to the vertical generatrix of the rod - at a low level of sediment providing optimal spiral motion of the heated sediment flow with the installation of such a monitor in ntre tank. 1 Steam is supplied to monitors with a pressure above 1 atmosphere. Steam is passed through the nozzles of the ejector heads, heating the precipitate and causing a vacuum to appear at one end of the head and the sediment to be drawn into the ejector cavity, and the pressure created by the steam at the other end to heat and push the heated sediment out of the ejector cavity. The formation of multidirectional flows of heated sediment occurs, leading to effective dilution and mixing of the entire volume of sediment in the tank. Pipelines and at least one pump used for pumping liquefied and mixed product are mounted at the tank. The screw (sediagonal) pump is most efficiently used for pumping liquefied deposits from tanks with a high content of mechanical impurities (including inclusions of large particles) through a siphon valve to a sump, to a centrifuge (another decanter), a free filter, in other words, to objects not creating, or creating little resistance. It is recommended to use this type of pump for pumping deposits through a long (over 100 meters) pipeline, or into a process pipeline with a pressure above 3 atmospheres. This type of pump is slightly sensitive to the presence of mechanical impurities in the sediment (inevitably mixed due to ejectors with the main volume of hydrocarbon sediment), and also has a certain suction height, which makes it possible to more efficiently use the capabilities of the siphon valve, but is limited by pressure characteristics. A piston pump is effective in pumping well-heated sediment with a minimum content of solids over long distances, or into collectors under high pressure.

A decrease in the content of mechanical impurities can be achieved by operating monitors against the background of water previously introduced into the tank (in volume - not less than the volume of sediment), followed by sediment sedimentation to achieve its natural separation inside the tank into a hydrocarbon layer, water and mechanical impurities, after whereby the settled hydrocarbon layer is pumped out through a siphon valve with adjustment of its quality (the presence of water in it) by turning the valve.

Vacuum pumps are effective in pumping sludge of any degree of heating, dilution and almost any consistency. Their main disadvantage is the low productivity of the pumped product. Example 2. Steel vertical tank with a pontoon or roof.

The design of such reservoirs differs in that on floating roofs and pontoons of such reservoirs there are either no hatches at all that allow monitors to enter the cavity, or such hatches relative to the tank area are not enough. Therefore, when heating the sediment in such tanks, monitors of a special design are used. It is based on the fact that the common feature of all pontoons and floating roofs is the presence of supports fixed to their external part, and the presence of a gap between the pontoon (floating roof) and the tank wall. Dismantling the pontoon supports releases holes with a diameter of 80 mm, through which monitors can enter the cavity. In this case, the monitor is fixed on the flange, to which the support was previously attached. In addition, it is possible to enter the monitor into the gap between the pontoon and the tank wall. In all cases, a monitor is used either with one nozzle or with several nozzles directed in one direction. Example 3. An underground (buried) tank.

Similar to a tank without a pontoon. . with a rather low productivity, or to prime pumps of various types. The most successful arrangement is the sequential aggregation of a submersible pump (lifting a heated sediment from a depth) and a screw (sedimentary) pump (transporting sediment over a long distance). After removal from the reservoir, the sediment, depending on its physical and rheological composition, as well as on the tasks to be solved, can be directed: - to mix with salable oil; - for separation and subsequent disposal of the separated fractions; -to dispersion; - for burial.

Claims (12)

1. A device for cleaning the tank from viscous oil deposits and viscous deposits of oil products, containing means for heating, liquefying, moving and mixing said deposits, including ejector means, and means for removing and transporting liquefied deposits, characterized in that said ejector means is made in in the form of a monitor, consisting of a hollow rod, designed to supply through it into the reservoir of the working fluid in the form of water vapor or gas, or liquid installed in the upper part of the head ngi mounting device, and connected to the lower part of the rod of at least one ejector head for sucking, heating, liquefying, homogenizing deposits and moving liquefied deposits, the axis of at least one ejector head is located at an angle to a plane perpendicular to the axis rods.  2. The device according to claim 1, characterized in that the axis of the at least one ejector head intersects the axis of the rod.  3. The device according to claim 1 or 2, characterized in that the axis of at least one ejector head does not intersect the axis of the rod.  4. The device according to any one of claims 1 to 3, characterized in that the monitor contains a pair of ejector heads, each of which is rigidly fixed to the rod at an angle to the horizontal.  5. The device according to any one of claims 1 to 3, characterized in that the monitor contains two pairs of ejector heads, rigidly fixed to the rod and located at the same level at an angle to each other.  6. The device according to any one of claims 1 to 3, characterized in that. that the monitor contains two pairs of ejector heads, rigidly fixed on the rod and located at different levels at an angle to each other, while the ejector heads of one pair are located at an angle to the horizontal.  7. The device according to any one of claims 1 to 6, characterized in that the monitor is made to rotate about the axis of the rod, and the ejector heads are rotatable relative to the rod itself.  8. The device according to any one of claims 1 to 7, characterized in that the monitor is made in the form of a steam, pneumatic or hydraulic monitor, and its nozzles have different sections.  9. The device according to any one of claims 1 to 8, characterized in that the rod is made with the possibility of axial movement relative to the mounting device and fixation on it in the selected position.  10. The device according to any one of claims 1 to 9, characterized in that the mounting device is made in the form of a cross.  11. The device according to any one of claims 1 to 10, characterized in that the rod consists of several parts for changing its length. 12. The device according to any one of claims 1 to 11, characterized in that the means for the removal and transportation of liquefied deposits is made in the form of at least one pipeline and pump.