RU196848U1 - Camera for cleaning and diagnostics, made from tube blanks - Google Patents

Abstract

The utility model is designed to be installed on stationary launch and receiving units and is used to receive in-pipe cleaning, diagnostics, sealing and separation devices in the flow of the pumped product. The camera receiving means of cleaning and diagnostics for pipelines contains a main body, an additional body made of pipe blanks, a shutter and supports. The supports are connected to the main body. An eccentric adapter connects the main body to the secondary body. The camera is equipped with a catcher, mechanically fixed in the main body, and two tees welded to the ends of the main body. The shutter is connected by welding to the end of one of the tees, and the eccentric adapter is connected to the end of the other tee. The technical result consists in increasing the reliability of the operation of technological pipelines. 6 c.p. f-ly, 2 ill.

Description

The utility model is intended for installation on stationary launch and receiving units and is used for receiving in-line cleaning, diagnostics (SOD), sealing and separation devices in the flow of the pumped product.

A well-known mobile camera for starting / receiving SOD for pipelines, including a housing, a shutter, nozzles for supplying a medium, draining technological operations and measuring pressure, and supports. The camera is equipped with a quick-connect for fastening to the pipeline, while the supports contain a sliding section with a lock and a jack (RU 165236, IPC V08V 9/04, F16L 55/46, publ. 10.10.2016).

The disadvantages are:

 the presence of a not-so-reliable quick-release coupling in the form of a cap-tightening clamp;

 the presence of screw supports with a jack - problems with lifting a large weight of SOD to large nominal diameters.

A device is known for starting and receiving in-line means in a pipeline containing a main cylindrical section, one end of which is provided with a shutter that blocks access to the inlet start-up chamber of in-line means located inside the cylindrical section, and the other end is provided with a docking flange. A removable transition section equipped with a backup device is attached to the connecting flange of the main section through its flange, the inner diameter of the transition section is equal to the internal diameter of the pipeline, and the diameter of the connecting flange of the main section is equal to the diameter of the transition section flange, and the main section is mounted on supports equipped with height-adjustable racks (RU 155544, IPC F17D 3/08, published on 10/10/2015).

The disadvantages are:

 connecting flanges - less reliable connection than welding;

 the use of a clamp lock is an outdated technology that needs much more time for open / close cycles.

Known temporary camera receiving means of cleaning and diagnostics of pipelines, including a cylindrical body with an end shutter on one side, located on the other hand and rigidly connected to the body of the eccentric transition section having a cylindrical part with an output diameter corresponding to the diameter of the pipeline and made with the possibility of welding to the pipeline , a support frame rigidly connected to the housing, while the chamber has technological nozzles for supplying oil, for discharging air, for draining the worker the second medium from the chamber and install the pressure gauge, the support frame designed as a slide, wherein the ratio of the minimum length of the chamber and the diameter of the passage section of the cylindrical portion of transition section D _n by increasing the diameter of the latter is reduced, the flow cross section diameter ratio of the housing chamber D _p and the diameter of the flow cross section of the cylindrical portion the transition section D _n when the diameter of the passage section of the housing 200-400 mm and 600-1300 mm decreases with increasing diameter of the passage section of the housing, the ratio of the distance from the end of the shutter to the first oil supply pipe from it and the diameter of the housing cross section Д _р decreases with increasing diameter of the housing cross-section Д _Р with the value of the latter from 200 to 350 mm and from 600 to 1300 mm, the ratio of the distance between the oil supply pipes and the diameter of the passage housing section D _p is reduced when the value of the last 200 to 350 mm and from 500 to 1300 mm in diameter with increasing passage section of the body, the ratio of the distance from the base of the support frame to the housing axis and the diameter of the flow cross section in the housing enshaetsya with increasing diameter of the passage section of the housing. (RU 52460 U1, IPC F17D 3/08, published March 27, 2006).

The disadvantage is the lack of reliability.

A well-known start-up chamber for receiving SOD of the linear part of main oil pipelines, designed to be installed on stationary start-up and receiving units and serving for starting and receiving in-line SOD in the pumped product stream, including a main body, a shutter, an additional body and supports, while the main body and additional the housing is connected by an eccentric adapter (RU 180891 U1, IPC V08V 9/057, F16L 55/46, publ. 06/29/2018). Taken as a prototype.

The camera includes: a main body (extended part), an additional body (nominal part) made of tube blanks, an eccentric adapter, an end lock and supports.

The disadvantages of this device are:

 the possibility of penetration through the pipe outlet of the product elements of the destroyed sealing devices;

 the use of mortise branch pipes for product outlet.

The objective of the utility model is to create a camera for receiving SOD for pipelines with high operational characteristics.

EFFECT: increased reliability of operation of technological pipelines.

The problem is solved, and the technical result is achieved due to the fact that the camera receiving means of cleaning and diagnostics for pipelines contains a main body and an additional body made of pipe blanks, a shutter, supports connected to the main body, an eccentric adapter, a catcher, fixed mainly mechanically the case, and two tees welded to the ends of the main body, the valve being connected by welding to the end of one of the tees, and the eccentric adapter to the end of the other tee to connect the main body to secondary body.

In particular cases, the claimed utility model can be performed as follows.

The trap can be cylindrical in shape and can consist of longitudinal rods located around the perimeter of the trap, fastened on the outside by rings, while the trap rings are located with a smaller pitch opposite the tees than the rings located on the rest of the trap.

The trap can be made of intrinsically safe material, while an aluminum alloy can be used as the intrinsically safe trap material.

Supports can be made in the form of racks of rectangular cross-section, each of which is installed in the base with the ability to move inside the base in the direction of the longitudinal axis of the camera.

In the lower part of the uprights on opposite sides can be made of the protrusions included in the grooves made in the base of the support.

The essence of the claimed utility model is illustrated by the drawings, which depict the inventive camera receiving means of cleaning and diagnostics for pipelines.

Items in the drawing:

1 - main body (extended part),

2 - eccentric adapter,

3 - additional housing (nominal part),

4 - shutter

5 - supports

6 - catcher,

7 - tee (Fig. 2).

The camera for receiving cleaning and diagnostic tools for pipelines contains a main body (1), an additional body (3) made of pipe blanks and interconnected, a shutter (4), and supports (5). The supports (5) are connected to the main body (1). The trap (6) is mechanically fixed in the main body (1). Two tees (7) are welded to the ends of the main body (1). The shutter (4) is connected by welding to the end of one of the tees, and the eccentric adapter (2) to the end of the other tee (7) to connect the main (1) body and the additional (3) body.

The device operates as follows. To ensure the reception of the flow means, the location of the flow means in the main body (1) (the expanded part of the chamber) is controlled. In this case, the head part of the flow means passes into an additional housing (3) (nominal part) by means of an eccentric adapter (2). During the operation of the SOD receiving chamber for pipelines, the product flow passes into the tees, which serve to divert the product (7). After depressurization, the end valve (4) is opened and the trap (6) is removed with the elements of the sealing devices inside it, which are a special case of in-line means.

Using for the manufacture of the main body and the additional body of the camera receiving means of cleaning and diagnostics for piping tube blanks compared with shells of sheet material, which are used in most cases for the manufacture of the main body, reduces the number of welds. Also reduces the number of welds, the use in the design of the camera receiving means of cleaning and diagnostics of tees as a single product as a means of removal of the product.

This reduction in the number of welds, which are a possible cause of the defect, increases the reliability of operation of technological pipelines, as it significantly reduces the risk of structural failure along the weld.

The presence in the design of the receiving chamber of the means of cleaning and diagnostics of the trap makes it possible to exclude the penetration of elements of destroyed sealing devices into technological pipelines, which also increases the reliability of operation of technological pipelines, since it eliminates clogging of filters by elements of destroyed sealing devices.

Also, to exclude additional welds, the tees can be made of an asymmetric shape, which eliminates the use of an additional element connected to the tee to ensure the overall size of the chamber, and they can also be made equally through with the main body to prevent the formation of a transition that could damage the cleaning agents and diagnostics for their extraction.

The implementation of the cylindrical trap made of longitudinal rods located along its perimeter, fastened on the outside by rings located with a smaller pitch opposite the tees than the rings located on the rest of the trap, ensures that elements of destroyed sealing devices do not get into the process pipelines.

To ensure the safety of the claimed chamber for receiving cleaning and diagnostic tools for pipelines, the trap is made of intrinsically safe material, while an aluminum alloy is used as the intrinsically safe trap material.

To ensure the movement of the camera along the longitudinal axis from temperature deformations, the supports are made in the form of rectangular posts, each of which is installed in the base, made with the possibility of fastening to the foundation, for example, by means of foundation bolts, with the possibility of movement in the direction of the longitudinal axis of the camera, the lower part of the uprights on opposite sides are made of protrusions included in the grooves made in the base.

Claims (7)

1. A camera for receiving cleaning and diagnostic tools for pipelines, comprising a main body, an additional body made of pipe blanks, a shutter, supports connected to the main body, and an eccentric adapter, characterized in that it is equipped with a trap mechanically fixed in the main body, and two tees welded to the ends of the main body, while the shutter is connected by welding to the end of one of the tees, and an eccentric adapter to the end of the other tee to connect the main body with additional An additional housing. 2. The chamber according to claim 1, characterized in that the trap is made of cylindrical shape and consists of longitudinal rods located around the perimeter of the trap, fastened on the outside by rings. 3. The chamber according to claim 2, characterized in that the catcher rings are arranged with a smaller pitch opposite the tees than the rings located on the rest of the catcher. 4. The camera according to any one of paragraphs. 1-3, characterized in that the trap is made of intrinsically safe material. 5. The chamber according to claim 4, characterized in that an aluminum alloy is used as an intrinsically safe trap material. 6. The camera according to claim 1, characterized in that the supports are made in the form of racks of rectangular cross-section, each of which is installed in the base with the ability to move inside the base in the direction of the longitudinal axis of the camera. 7. The chamber according to claim 6, characterized in that in the lower part of the uprights on opposite sides there are protrusions included in the grooves made in the base.

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