DE29613522U1 - Pipeline pig - Google Patents

Description

I.S.T. Molchtechnik GmbH , Albert-Schweitzer-Ring 23, 20355 Hamburg

Pipeline pig

The invention relates to a pipeline pig with a pig body having a front and a rear face, with at least one sealing surface on the circumference of the pig body between the front and rear faces, and with at least one channel connecting the front and rear faces of the pig body.

Such a pipeline pig is known from the state of the art, with which powder or granules are transported through pipelines. The known pig is also used to remove deposits on the inside walls of pipes or to flush out blocked pipelines. For this purpose, a gaseous or liquid propellant, e.g. air, nitrogen or water, is pressed through the pipe. The pressure exerted by the propellant on the rear of the pig body drives the pig through the pipe. Powder located in front of the pig can thus be easily pushed through the pipe. Alternatively, wall deposits can be removed that are caught by the peripheral edges of the pig. Channels arranged in the pig body that connect its front to its rear increase its effect: propellant that passes through the channels from the rear to the front of the pig exits at high speed from the channel openings on the front. The powder to be transported is whirled up and can be pushed more easily by the pig in front of it.

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In this way, the powder does not solidify due to the pushing effect of the pig and the pig is prevented from getting stuck. If wall deposits need to be removed, they will break off more easily due to the propellant escaping from the channel openings.

The channels of the known pig increase its effectiveness, but handling the pig is cumbersome. After passing through the desired pipe section, the pig must be driven forward to the next pipe opening and can only then be removed from the pipe and, if desired, reinserted at the starting point. This process is not only time-consuming, but also requires increased attention from the user, since when reinserting the pig at the starting point, attention must be paid to how the pig is to be inserted into the pipe. A pig body that does not have channels, on the other hand, can remain in the pipe and be driven back in the pipe with a second driving medium acting on the front of the pig.

From DE 30 32 532 a pipeline pig is known which has two spaced-apart ring-cylindrical sealing surfaces with the same diameters, between which the pig body is radially constricted. A spherical section is arranged on the side of the sealing surfaces facing away from the constriction, and the distance between adjacent sealing surfaces is equal to or smaller than the inner pipe diameter. The two sealing surfaces of this pipeline pig are designed so that they have contact with the inner pipe wall over their entire circumference.

The object underlying the invention is to further develop a pipeline pig of the type mentioned at the beginning in such a way that the pig can be easily driven back in the pipe to the starting point and removed at the starting point.

This object is achieved according to the invention in the pipeline pig of the type mentioned at the beginning in that at least one valve opens the channel in one direction and blocks it in the opposite direction.

The advantages of the invention are in particular that the pig can remain in the pipe for the return transport. When pigging the pipe, for example when transporting a powder, a first propellant passes through the channels and through the open valves to the front of the pig body and supports the pigging process in the manner described above. After reaching the

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A second driving medium is used to act on the front of the pig body to reach the desired end point in the pipe. The valves then block the channel and prevent the flow of the second driving medium, which then drives the pig back through the pipe to the starting point.

In a preferred embodiment of the pipeline pig according to the invention, the front and rear of the pig body are convexly shaped. This minimizes the risk of the pig becoming jammed or stuck when driving forwards or backwards. It is also advantageous if the pig body - as described above - has two spaced cylindrical sealing surfaces of the same diameter between the front and rear. Preferably, the distance between the adjacent sealing surfaces is equal to or smaller than the inner diameter of the pipeline. A waist that radially constricts the pig body and is arranged between the sealing surfaces complements the advantageous properties. With this pipeline pig designed in this way, the pig can be transported in both directions, even through pipelines with tight bends. Furthermore, its sealing effect is also maintained if, for example, first the first sealing surface and then the second sealing surface successively drive over weld irregularities.

In a particularly advantageous embodiment of the pipeline pig according to the invention, several channels are arranged in the pig body. This ensures that the first propellant emerging from the channel openings covers the particles to be transported or removed in front of the pig body over as much of the entire surface as possible. The arrangement of the channels can vary depending on the intended use: When transporting powders or granules, it is expedient for the first propellant emerging through the channel openings to cover the entire area perpendicular to the direction of movement of the pig. If, on the other hand, deposits on the inner walls of the pipe are to be removed, the channel openings are preferably directed towards these deposits.

The arrangement of the channels connecting the front and rear of the pig body can be of various types. A preferred design provides that one section of a channel runs from one front surface to the waist and another from the waist to the other front surface. In this case, the first propellant medium passes through the first-mentioned channel section to the space enclosed by the waist and the inner wall of the pipe and from there through the last-mentioned channel section to the other front surface.

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The channel sections connecting the front surfaces and the waist can be designed in different ways. A channel section can, for example, be formed by a hole that connects a front surface to the waist. Alternatively, a channel section is conceivable that runs along the peripheral edge of a sealing surface, e.g. in the form of a notch, from a front surface to the waist.

Channels can also run through the pig body along their entire length. In this case, a single hole is sufficient to form a channel. It is of course possible to arrange both continuous channels and channels consisting of several different channel sections next to one another in a single pig body.

The design of the valves for the passage of the first propellant medium through the pig body can be implemented in various ways. A particularly preferred design provides that a membrane, which is arranged on the surface of the pig body, covers a channel opening and opens the associated channel in the flow direction of the first propellant medium and seals it in the opposite direction. The membrane is lifted by the first propellant medium, which flows through the channels. When the pig is transported back, the second propellant medium presses the membrane against the channel opening and the channel is blocked.

If the pig body has channel sections that run from the rear to the waist, it is advantageous if a single ring-shaped membrane runs around the waist of the pig body and rests on the mouths of these channel sections. Of course, in this design the membrane must not cover the channel sections that run from the pig waist to the front of the pig body. The ring-shaped membrane has the advantage that it is largely protected from the particles to be conveyed or removed. The risk of particles settling between the membrane and the waist surface and thereby impairing the valve effect is therefore small.

In another embodiment, a membrane resting on a surface section of the front covers the channels opening there. The membrane is then sufficiently lifted by the first driving medium flowing through the channels, while the second driving medium flowing in from the other end of the pipe presses the membrane against the channel openings and blocks the channels.

In another advantageous design of the pipeline pig, individual valves have a flap that is arranged in a channel or at the mouth of a channel. This flap only opens when the propellant is pressed through the channels from the rear of the pig body. If the flow direction is reversed, the flaps close the channels.

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A preferred design of the pipeline pig is one in which individual valves are designed as any check valves. These can be arranged both in the channel and at an opening of the channel. Ball valves, for example, can be considered as check valves.

The invention is explained in more detail below with reference to the drawing. They show:

Fig. 1 is a side view of a pipe fitting according to the invention in

a pipe, shown conveying a transport medium;

Fig. 2 the pipeline structure of Fig. 1 in the same view, shown at

the return in the pipe;

Fig. 3 is a side view of an alternative embodiment of the pipeline pig according to the invention, partly in section;

Fig. 4 is a front view of the pipeline pig of Fig. 3.

The pipeline pig shown in Fig. 1 and 2 is located in a pipe R. It has a pig body 1 with a front 2 and a rear 4, which are each convexly shaped. Between the front 2 and the rear 4 there are two spaced cylindrical sealing surfaces 8 with the same diameter. The sealing surfaces 8 are constantly in contact with the inner pipe wall I under pre-stress, which ensures effective sealing. The distance between the adjacent sealing surfaces 8 is chosen to be equal to or smaller than the inner diameter of the pipe R. Between the sealing surfaces 8 the pig body 1 has a radially constricted waist 6. Due to the selected distance between the sealing surfaces 8 and the waist 6 it is possible to pass through very narrow pipeline bends.

An additional recess 40 is shown inside the pig body 1 in Fig. 3 and 4. A transmitter or another component for determining the position of the pipeline pig in the pipe can be accommodated in this.

The pig body 1 of Fig. 1 has several channels 21 that run through the pig body 1 over their entire length. In the exemplary embodiment shown, the channels 21 run parallel to the inner pipe wall I. The channels 21 each have two channel openings: one channel opening 23 is arranged on the rear face 4, the other channel opening 25 on the front face 2. Check valves 30 are arranged at the channel openings 25.

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In the embodiment shown, a transport medium M, which is located in front of the front 2 of the pig body 1, is to be conveyed in the direction of the arrow with the help of the pig body 1. For this purpose, a first propellant T1 exerts pressure on the rear 4 of the pig body 1 and drives it forward. Part of the first propellant T1 enters the channels 21 through the channel openings 23. Because the channel cross section is small compared to the inner cross section of the pipe, these parts of the first propellant T1 exit at high speed at the channel openings 25 on the front 2. The transport medium M is thereby loosened, and clumping of the transport medium M and, as a result, reduced transport performance or even the pipeline pig getting stuck are prevented.

When the pipeline pig has reached the end point of the transport route, the supply of the first driving medium T1 is interrupted. The pipeline pig according to the invention is left in the pipe R for return transport. The pig body 1 is driven back to the starting point by a second driving medium T2, which acts on the front 2 (Fig. 2). The check valves 30 block the channel during this process. The entire pressure exerted by the second driving medium T2 on the front 2 is therefore available for the return transport of the pig body 1.

Figures 3 and 4 show another embodiment of the pipeline pig with different types of channel sections 20, 26, 28 connected in series in a pipe R. From the rear face 4 of the pig body 1, channel sections 20 run through the pig body 1 to the waist 6. The subsequent channel section 26 is formed by the space between the waist 6 and the pipe inner wall I. The following channel section runs from the waist 6 to the front face 2 and is formed by notches 28 in the sealing surface 8. On the waist 6 of the pig body 1 lies an annular, endless membrane 30' which covers the channel openings 24 of the channel sections 20. If the first driving medium T1 passes from the rear 4 of the pig body 1 through the channel openings 22 into the channel sections 20, the membrane 30' resting on the channel openings 24 is lifted by the driving medium T1. The driving medium T1 can then pass through the channel section 26 through the notches 28 to the front 2 in order to loosen a transport medium in the adjacent pipe section or to remove wall deposits.

If the pig is driven back to the starting point in the pipe R, the second driving medium T2 acting on the front 2 passes partly through the notches 28 into the channel section 26 enclosed by the waist 6 and the pipe inner wall I. The pressure of the driving medium T2 presses the membrane 30' against the channel mouth.

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ings 24 of the channel sections 20 and thus prevents the second propellant medium T2 from passing through the channel sections 20. As a result, the pig is driven back to the starting point by the pressure exerted by the second propellant medium T2 on the front 2 and the tail 6 of the pig body 1. The membrane 30' acts as a valve which opens the channels 21' in one direction and blocks them in the opposite direction.

Due to the design according to the invention, it is possible to operate the pig even in fully automatic systems.

Claims (15)

EXPECTATIONS 1. Pipeline pig with a pig body having a front (2) and a rear (4) with at least one sealing surface (8) on the circumference of the pig body (1) between the front {2} and the rear (4), with at least one channel (21; 21') connecting the front (2) and rear {4} of the pig body (1), characterized by at least one valve (30; 30') which opens the channel (21; 21') in one direction and closes it in the opposite direction. 2. Pipeline pig according to claim 1, characterized in that one or more channels (21; 21') are provided in the pig body (1). 3. Pipeline pig according to claim 1 or 2, characterized in that the front (2) and rear (4) of the pig body (1) are convexly shaped. 4. Pipeline pig according to one of the preceding claims, characterized in that the pig body (1) has two spaced cylindrical sealing surfaces (8) of the same diameter between the front (2) and rear (4). 5. Pipeline pig according to claim 4, characterized in that the distance between the adjacent sealing surfaces (8) is equal to or smaller than the inner diameter of the pipe. 6. Pipeline pig according to claim 4 or 5, characterized in that a waist (6) radially constricting the pig body (1) is provided between the sealing surfaces (8). 7. Pipeline pig according to claim 6, characterized in that at least one channel section (20) runs from one front surface (4) to the waist (6) and at least one further channel section (28) runs from the waist (6) to the other front surface (2). -9- 8. Pipeline pig according to claim 7, characterized in that at least one channel section (20) from a front surface (4) through the pig body (1) to the waist {6}. 9. Pipeline pig according to claim 7 or 8, characterized in that at least one channel section (28) runs through a sealing surface (8) on the peripheral edge. 10. Pipeline pig according to one of the preceding claims, characterized in that a channel (21) runs through the pig body (1) over its entire length. 11. Pipeline pig according to one of the preceding claims, characterized in that individual valves contain a membrane (30') which is arranged on the surface of the pig body (1) and releases the associated channel (21; 21') or channel section (20) in one flow direction of the driving medium and blocks it in the opposite direction. 12. Pipeline pig according to claim 11, characterized in that the membrane (30') is ring-shaped and runs around the waist (6) of the pig body (1). 13. Pipeline pig according to claim 11, characterized in that a membrane resting on a surface portion of the front (2) covers the mouth (25) of the channel (21; 21'). 14. Pipeline pig according to one of claims 1 to 10, characterized in that individual valves have a flap which is arranged in a channel (21; 21') or at an opening (23, 25; 22, 24) of a channel (21; 21'). 15. Pipeline pig according to one of claims 1 to 10, characterized in that individual valves are designed as check valves (30) which are arranged in a channel (21; 21') or at an opening (23, 25; 22, 24) of a channel (21; 21') or channel section (20).