RU197442U1 - Stationary sludge erosion device - Google Patents

Abstract

The utility model relates to equipment for use in the oil and refining industries, in particular to a sludge erosion system installed directly in horizontal devices with elliptical bottoms (SEE apparatus) such as oil and gas separators, water and oil sumps, electric dehydrators, etc. The stationary erosion system sludge, comprising a closed loop housing, supply nozzles and nipples, characterized in that the system includes a closed housing contour located directly in the horizontal apparatus, formed by a collapsible connection of parallel longitudinal and transverse pipes, as well as supply nozzles and supply nozzles interconnected by a collapsible Using the proposed design of a stationary system for washing out the slurry of a horizontal apparatus reduces the complexity of installation and subsequent repair and maintenance work, improves the quality of cleaning the SEE apparatus, and reduces the time and labor costs for testing denia cleaning apparatus SEE from sludge. 6 c.p. f-ly, 5 ill.

Description

The utility model relates to equipment for use in the oil and oil refining industries, in particular, to a sludge erosion device installed inside horizontal apparatuses with elliptical bottoms (hereinafter, SEE apparatus) such as oil and gas separators, water and oil sumps, electric dehydrators, etc.

The prior art method for cleaning reservoirs of oil deposits, including pumping wash liquid, circulating a liquefied product, introducing depressants that affect the asphalt-resin-paraffin deposits and providing fluidity, and separating the product into oil, aqueous fraction and mechanical impurities, heat the tank with a coolant with the use of structural elements of the tank (see patent RU 2109583 C1, IPC B08V 9/08, publ. 04/27/1998).

The disadvantages of these sludge washing devices are the need to heat the tank from the inside with coolant, pump the wash liquid, then mix the diluted product with the addition of depressants, and then separate the product into oil, water and solids inside the tank.

The known method, which includes introducing the working end of the flexible pipe in the form of a wash head into the treatment area, supplying it with a washing liquid under pressure, moving the wash head along the treatment area along a predetermined path, while the working end of the pipe is equipped with an additional perforated pipe section hermetically connected to with a wash head, the working end of the pipe is introduced into a sealed oil preparation tank, the pressure on the working end of the pipe is set to 0.8-1.0 MPa, it is moved inside the tank at a speed not greater less than 1 m / min with a pulling force on the working end of the pipe of 2-3 kg / cm ² , while the flow of flushing fluid supplied to the tank is maintained at the rate of 8-10 m per 1 m ^{3 of} slurry during the entire washout and sedimentation cycle deposits (see patent RU 2226607 C2, IPC E21B 43/24, B08B 9/08, publ. 04/10/2004).

The disadvantages of this sludge erosion device are the need to use additional equipment, the lack of the ability to automate the frequency of sludge erosion, a non-separable design, and increased complexity of installation, repair and maintenance work.

Closest to the claimed utility model is a device for cleaning the bottom and vertical walls of a stationary vertical tank for storing oil from bottom sediments (see patent RU 2314882 C2, IPC BVB 9/093, publ. 20.01.2008), including a housing, a supply pipe working agent (pipe), an annular collector (in the claimed solution, the housing is in the form of a rectangular closed loop, representing parallel longitudinal and transverse pipes), equipped with jet nozzles (nipples) located on the inner and outer pov ited annular collector at a distance of 1.5 m from each other wherein the collector has a diameter of 0.5 L tank.

The disadvantages of the closest invention are the need to heat the tank from the inside with coolant, pump wash liquid, then mix the diluted product with the addition of depressants, and then separate the product into oil, water and mechanical impurities inside the tank, the inability to automate the frequency of sludge erosion, non-separable design, increasing complexity installation, repair and maintenance work, in addition, this invention applies to tanks vertical and cannot perform its functions in horizontal devices.

The technical task to which the claimed utility model is directed is to create a simple and reliable design installed inside the SEE apparatus, which allows to reduce the complexity of installation, repair and maintenance work.

The technical result from the use of the proposed design of a stationary device for washing away sludge installed in the apparatus of SEE is to reduce the complexity of installation, repair and maintenance work by dividing the design of the device into parts.

The technical result is achieved by the fact that the stationary sludge erosion device is located directly in the horizontal apparatus, including the supply nozzles, nipples and the housing in the form of a closed loop formed by a collapsible joint of parallel longitudinal and transverse pipes, as well as the supply nipples and feed nozzles connected by a collapsible joint .

The essence of the utility model is described below based on the drawings of FIG. 1 and FIG. 3, which shows a general view of a stationary sludge erosion device, with supply nozzles connected through a flange connection to the supply fittings installed in the cylindrical part of the horizontal apparatus, FIG. 2 and FIG. 4, which shows a general view of a stationary sludge erosion device, with supply nozzles connected through a flange connection to the supply fittings installed in the end elliptical bottoms of the housing of the SEE apparatus; FIG. 5 - direction of the nipples.

In the drawings, the structural elements of a stationary sludge erosion device are indicated by the following positions:

1 - feed pipe;

2 - casing in the form of a rectangular closed loop of parallel longitudinal and transverse pipes;

3 - additional transverse pipe;

4 - supports for stationary sludge erosion device;

5 - nipple;

6 - a collar;

7 - flange connection;

8 - supply nozzle;

9 - tee.

A stationary sludge erosion device installed directly in the SEE apparatus (Fig. 3 and Fig. 4) includes a housing 2 in the form of a rectangular closed loop of parallel longitudinal and transverse pipes, which are collapsible and are fastened to each other by flange connections 7. The housing 2 is attached to the supports 4 , using clamps 6. The housing 2 is connected to the supply pipes 1 using tees 9 welded to them. The supply pipes 1 are connected on one side to the housing 2 using tees 9 welded to them, and on the other hand to the supply pieces zeros 8 by means of a flange connection 7. Also, additional transverse pipes 3 are attached to the housing 2 by means of a flange connection 7, to which tees 9 are welded, at the other ends of which there are flanges (Fig. 1 and Fig. 2). Nipples 5 are welded to the body 2 and additional transverse pipes 3 (Figs. 1, 2, 5). The housing 2 is collapsible, and its elements are mounted between the flange connections 7.

This utility model is illustrated by an example of a stationary slurry erosion device, which clearly demonstrates the possibility of obtaining the specified technical result.

A stationary sludge erosion device is installed directly in the SEE apparatus and operates as follows: high-pressure water through the supply pipes 1 fills the housing 2 and additional transverse pipes 3. The injected water, leaving through the nipples 5, creates high turbulence and shakes up the sludge layer into a thick liquid, which is discharged through the drainage system of the SEE apparatus. When installing the injection pump, the stationary sludge erosion device will turn on after a specified number of release cycles for the SEE apparatus.

Installation of a stationary sludge erosion device inside the SEE apparatus eliminates the use of additional portable equipment necessary for cleaning the internal surface of the SEE apparatus from sludge generated during operation, and, accordingly, reduces the complexity of mounting and dismounting this equipment. A stationary sludge erosion device installed directly in the SEE apparatus is in constant readiness for cleaning the inner surface of the SEE apparatus from sludge.

The design of the stationary device for washing the sludge collapsible reduces the complexity of installation and subsequent repair and maintenance work.

This device presents a case in the form of a rectangular closed loop of parallel longitudinal and transverse pipes, the nominal diameters of which can be from 50 to 100 mm, which is mounted on supports at a height of 300 - 400 mm from the horizontal apparatus body around the entire perimeter.

The supply pipes are connected on one side to the housing using tees welded to them, and on the other hand, to the supply fittings 8 using a flange connection 7. Also, additional transverse pipes 3 are attached to the housing 2 with a flange connection 7, to which the tees 9 are welded, at the other ends of which are flanges.

By means of welding, tees are attached to the additional transverse pipes, to which, on the other hand, flanges are connected by welding. Also, tees are connected by welding to the housing and to the supply pipes, which are secured to the supply fittings by means of a flange connection. This design makes it possible to ensure the collapsibility of the design of the supply pipes and additional transverse pipes with a housing, thereby reducing the complexity of installation and subsequent repair and maintenance work.

The nipples are made, for example, of low alloy or stainless steel, with internal diameters from 8 to 15 mm, fixed by welding to the body and with additional transverse pipes, where they are installed in two directions.

The installation angle of the nipples varies from 15 to 45 degrees (Fig. 5), and the distance between the nipples is in the range from 150 to 300 mm, which allows to increase the volume of agitated slurry and turn it into a thick liquid for withdrawal from a horizontal apparatus.

The use of a pump forcing washing liquid into a stationary sludge erosion device allows automating the entire process of sludge erosion.

The listed features are significant and interconnected with the formation of a stable set of essential features sufficient to obtain the specified technical result.

A comparative analysis of the proposed technical solution with identified analogues of the prior art showed that it is not known, and taking into account the possibility of industrial serial production of a stationary device for washing the slurry of a horizontal apparatus, we can conclude that it meets the criteria of patentability.

The proposed technical solution for a stationary device for washing out sludge and installing it in a SEE apparatus is of simple design, which simplifies the possibility of installation, repair and maintenance work.

The manufacture of the proposed stationary device for sludge erosion and its installation in a SEE apparatus does not require the development of new equipment and the re-equipment of existing facilities, and the tools used are widely used in petroleum engineering, which confirms the possibility of practical implementation, and accordingly, it is industrially applicable.

The proposed design of a stationary sludge erosion device and its installation inside the SEE apparatus is used in a number of oilfield and oil refining facilities.

The design of the sludge washout collapsible reduces the complexity of installation work, which ensures timely repair and maintenance work, which leads to an increase in the operational characteristics and efficiency of the sludge washout device.

Efficiency is ensured by the fact that the casing is made in the form of a rectangular closed loop of parallel longitudinal and transverse pipes, which are collapsible, with nominal diameters in the range from 50 to 100 mm, additional transverse pipes with diameters equal to the casing pipe diameters and are attached to the casing using tees and flange connections , nipples with inner diameters of 8 to 15 mm are installed at an angle of 15 to 45 degrees so that the distance between adjacent ones is in the range of 150 to 300 mm and directed inwards Twa, and when a stationary device erosion slurry injection pump will turn through a predetermined number of machine cycles SER release.

The above allows you to distribute the washing medium over the device and deliver it to the nipples, while creating the necessary pressure, so that the pressure at the outlet of the nipples, released through a given number of cycles, effectively creates high turbulence and shakes up the layer of sludge into a thick liquid that is discharged through drainage system of the SEE apparatus, and, directly affecting this, the dimensions of the parts of the device can only be maintained due to the fact that the device is collapsible, which can There is a timely repair and maintenance work.

Claims (7)

1. Stationary sludge erosion device, comprising a closed-loop casing, supply nozzles connected to the casing by welding to the casing pipes using tees, and nipples welded to the longitudinal and transverse pipes of a rectangular closed circuit of the device, characterized in that the device includes a directly placed in a horizontal apparatus, a closed contour of the device’s body, formed by a collapsible connection of parallel longitudinal and transverse pipes, as well as supply fittings and supply patr plugs interconnected by a collapsible joint. 2. The stationary sludge erosion device according to claim 1, characterized in that the collapsible parts of the stationary sludge erosion device are interconnected by flange connections. 3. The stationary sludge erosion device according to claim 1, characterized in that the nominal diameters of the parallel longitudinal and transverse pipes of the casing and additional transverse pipes are in the range from 50 mm to 100 mm. 4. The stationary sludge erosion device according to claim 1, characterized in that the nipples of the device with internal diameters of 8 mm to 15 mm are installed at an angle of 15 ° to 45 ° and are directed inside the horizontal apparatus. 5. The stationary device for washing away sludge according to claim 1, characterized in that the distance between the nipples of the device is in the range from 150 mm to 300 mm. 6. The stationary sludge erosion device according to claim 1, characterized in that the device nipples are made of low alloy or stainless steel. 7. The stationary sludge erosion device according to claim 1, characterized in that the supply nozzles are connected to the supply fittings and can be installed both in the cylindrical part of the horizontal apparatus and in the end elliptical bottoms of the horizontal apparatus.

Images