DE9409092U1 - Pipeline pig - Google Patents

Description

• m ···

01.06.94
Pipeline pig

The innovation relates to a pipeline pig on whose pig body two axially spaced spherical sealing surfaces are provided, whereby the diameter of the sealing surfaces essentially corresponds to the diameter of the pipeline receiving the pipeline pig.

A pipeline pig of the type described in the introduction is known, for example, from DE-OS 21 21 784. The pig shapes described in this publication are, on the one hand, difficult to clean due to their multi-part and fissured design and therefore cannot be used in the food and beverage sector for sanitary reasons, for example, and, on the other hand, these known pig bodies do not have the required strength and stability in many applications due to their freely deformable sealing surface edges. The pig geometry shown in Figure 4 of the aforementioned publication does not relate to a specific pig design, but this drawing merely shows other factors that determine the design of the pig body (see page 10). In addition, the shortest pipeline pig defined in the table on page 13 with a distance B=1.5D between the centers of the spherical sealing surfaces (see also Figure 4) allows a curve movement that is limited to pipe bends where the radius of curvature related to the center line is not less than 1.5 times the pipeline diameter.

Furthermore, DE 30 32 532 A1 describes a pipeline pig (see Figures 1 and 2) in which two axially spaced ball elements with the same diameter are connected to one another via various connecting elements. The axial distance between the spherical sealing surfaces should be approximately equal to or smaller than the diameter

of the pipeline. The aforementioned axial dimensioning requires special measures at branches of the pipeline so that this ball pig does not get stuck in the branch nozzle. In addition, the known ball pig is only suitable for pipe bends whose radius, based on the center line of the pipe bend, is not less than 1.5 times the pipe diameter. The design of the known ball pig in the connection area between its spherical sealing surfaces represents a problem area that is critical for cleaning, which is undesirable and not tolerated when using such a pig in the food and beverage sector, but especially in the chemical and pharmaceutical sectors.

The aim of this innovation is to further develop a pipeline pig of the type described above in such a way that it can be cleaned perfectly on all sides, has running and friction properties that correspond at least to those of known pipeline pigs, and that it is possible to pass through the narrowest commercially available pipe bends with the smallest possible oversize between the pipeline pig and the inside diameter of the pipeline or pipe bend.

This object is achieved by applying the characterizing features of claim 1. Advantageous embodiments of the proposed pipeline pig are the subject of the subclaims.

The pipeline pig according to the innovation has all the advantages of known ball pigs. Among other things, it can be driven through the pipeline in both directions and, even when driving through the narrowest commercially available pipe bends, it does not lose complete contact between its spherical sealing surfaces and the curved inner wall of the pipe bend. This is ensured by the fact that the longitudinal dimension of each partial ball

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is sufficiently long, with the spherical sealing surfaces extending symmetrically to the center of the partial spheres. The connecting body between the two partial spheres is constricted in its middle section to such an extent that there is a sufficient safety distance between its waist diameter and the inner wall of the pipe bend. In addition, the connecting body is connected tangentially to the partial spheres on both sides, in each case at a diameter point of the partial spheres, which is determined by the complete sealing of the pipeline pig when passing through the narrowest pipe bend used.

The characteristic dimensions of the pipeline pig according to the innovation are the distance A between the centers of the partial spheres, the minimum pig length B, its waist diameter T and its waist radius Rl in the middle part of its connecting body. According to an advantageous dimensioning rule, which is the subject of the present proposal, the aforementioned characteristic sizes are partly causally related to each other and partly to specified sizes. The specified sizes are the necessary minimum pig diameter D, the radius of curvature R of a pipe bend arranged in the pipeline with the largest curvature and, if applicable, the largest outlet diameter d of a branch used in the pipeline. On the one hand, a rounding radius r between the pipeline and a branch that may be provided with the outlet diameter d and a distance dimension t between the curved pipe wall and the waist diameter D of the pipeline pig can be freely selected within limits. A minimum pig body length B is obtained when, in the case of a branch to be provided, the outlet diameter d of the branch is designed with a nominal width smaller than the nominal width of the pipeline.

If the partial spheres of the pipeline pig are formed as complete hemispheres in the end area of the pig body, as another advantageous design according to the innovation provides, the pipeline pig can free itself from a T-branch; wedging is not possible under any circumstances.

Another advantageous design of the pipeline pig according to the innovation provides that the pig diameter D is dimensioned such that its minimum diameter corresponds to the maximum internal diameter of the pipeline or the pipe bend used. It is well known that pipes and pipe bends cannot be manufactured with absolute precision for fundamental but also economic reasons. They are subject to more or less large tolerances in terms of diameter and wall thickness. To ensure that the pipeline pig is perfectly sealed, it must therefore be dimensioned in the manner described above. Deviations in the pipelines and pipe bends within the permissible tolerances lead to increased friction and increased propulsion pressure when the pipeline pig is dimensioned accordingly, but not to a loss of the necessary complete sealing.

If the outlet diameter d of a T-branch used in the pipeline is designed to be one nominal diameter smaller than the nominal diameter of the pipeline containing the T-branch, the pipeline pig will find its shortest possible axial length according to the innovation, whereby automatic release from the branch nozzle of the T-branch is also ensured.

An example of the pipeline pig according to the innovation is shown in the drawing and is explained below.

Figure 1 a view of the pipeline pig with its
characteristic dimensions and

Figure 2 shows the pipeline pig according to the innovation when driving through a relatively strongly curved

Pipe bend according to DIN 11852 (R=I,125D), whereby the complete sealing conditions in all areas and the freedom of movement of the pipeline pig are illustrated.
10

Below the pipeline pig 1 (Figure 1) a T-branch with an outlet diameter d is indicated. The latter is designed with a nominal diameter smaller than the nominal diameter D of the pipeline that accommodates the T-branch. The branch is rounded towards the pipeline with a rounding radius r. From the illustration it can be seen that the distance A between the centers of the partial spheres 2 according to formula (1) is

A = d + 2r (1)

must be dimensioned so that the pipeline pig 1 cannot sink or become wedged in the branch.

If the outlet diameter d corresponds to that of the pipe D, the distance dimension A is given by

d = D (la)

from formula (1) to

A = D + 2r. (1)

The minimum pig body length B is calculated according to formula (2) as

Bl A(I + D/(2R)), (2)

where R is the radius of curvature relative to the center line of a pipe bend arranged in the pipeline with the greatest curvature used.

The waist diameter T is calculated from formula (3) as

T = D- 2(R - ^R2 - K*/A + t) , (3)

where the distance t between curved pipe wall and

The waist diameter T can be freely selected within certain limits. It is advisable to use t = 1 to 2 mm.

The waist radius Rl is given by formula (4)

a2 + (R - D/2 - Y<RD/2)2 - _a 2' + t)2 _R1 = _f

2(R- D/2 - ^(R-D/2)2 - a« + t where according to formula (4a)

a = A(2R - D)/(4R) (4a)

is to be set. From Figure 2 it is clear that the waist radius Rl necessarily results from the aforementioned sizes.

Figure 2 illustrates which conditions with regard to the axial length dimension BA of the partial balls 2 must be fulfilled so that the proposed pipeline pig 1 has a continuous sealing line on each sealing surface 2a of the partial balls 2 in a given pipe bend.
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To clarify specific pig dimensions, formulas 1 to 4a are applied to a pipeline pig 1 with a nominal width of DN 80; this assumes pipes made of stainless steel for foodstuffs in accordance with DIN 11850 and pipe bends for welding, 90 degrees, in accordance with DIN 11852.

DIN 11850 for pipes and DIN 11852 for pipe bends for welding result in a maximum internal diameter of the pipeline or pipe bend of D(R,max) - 81.7 mm. According to the above design rule, this results in a minimum pig diameter D(M,min) = 81.7 mm. It is assumed that a T-branch is used, the outlet diameter d of which is one nominal size smaller than the nominal size of the pipeline that accommodates the T-branch. The maximum internal diameter of the pipeline that is one nominal size smaller

is D(R,max) = d = 66.7 mm. With a selected rounding radius r = 5 mm (condition la), according to formula (1) the distance A = 76.7 mm and for a pipe bend with R = 90 mm in conjunction with formula (2) the minimum pig body length B = 111.5 mm. The waist diameter T of the pipeline pig 1 is then determined with an assumed distance dimension t = 2 mm according to formula (3) ?,u T = 60.5 mm. Finally, formulas (4) and (4a) with the above values result in a waist radius Rl = 36.2 mm.

Since dimensional deviations must also be accepted for the dimensions of the pipeline pig 1 depending on the manufacturing process in question, the characteristic dimensions of the pipeline pig 1 calculated above must be dimensionally tolerated by the expert in the necessary manner.

Claims (5)

a * 4··7 ·* ** ·&diams; ff 160DIV64 01.06.94 Protection claims 1. Pipeline pig, on whose pig body two axially spaced spherical sealing surfaces are provided, the diameter of the sealing surfaces essentially corresponding to the diameter of the pipeline receiving the pipeline pig, characterized in that the pig body (1) is made in one piece from elastomeric material, that the sealing surfaces (2a) are each formed from at least symmetrical partial balls (2) which are connected to one another by a connecting body (3) which is constricted in its middle part relative to the diameter (D) of the sealing surfaces (2a) and is tangentially connected to the partial balls (2) on both sides, that the longitudinal dimension of the partial balls (2) is selected in such a way that contact with the pipeline wall remains at the circumference of the sealing surfaces (2a) when the pig body (1) moves through curved sections of the pipeline, and that a distance (A) between the centers of the partial balls (2) and a waist diameter (T) of the middle part of the connecting body (3) is selected so that the middle part does not touch the pipeline when the pig body (1) passes its curved section. 2. Pipeline pig according to claim 1, characterized in that - the distance (A) according to formulas (1,1a), - a minimum pig body length (B)
according to the formulas (2,1,1a), - the waist diameter (T) according to the formulas (3,1,1a), and that - the constriction of the middle part of the connecting body (3) to the waist diameter (T) by a waist radius Rl according to the formulas (4,4a,1,1a)
measures: (1) A = d + 2r
(la) with d <_ D (2) B 1 A(I + D/(2R) ) (3) T = D- 2(R -*W ² - A2/4 ¹ + t) a2 + (R - D/2 - Y(RD/2) 2 - _a 2 + t)2 2(R- D/2 - V(RD/2)2 - _a 2 + t (4a) with a = A(2R - D)/(4R), where - with D the largest diameter of the partial spheres (2)
(D = D(M,min) = minimum pig diameter), - where d is the largest outlet diameter of a branch used in the pipeline and - where R is the radius of curvature relative to the center line of a bend of greatest curvature arranged in the pipeline are designated and where - a fillet radius r to the branch in the pipeline and - a distance dimension t between the curved pipe wall and Waist diameter T
can be freely selected within limits. 3. Pipeline pig according to claim 1 or 2, characterized in that the partial spheres (2) are each formed as complete hemispheres (2, 4) in the end region of the pig body (1). 4. Pipeline pig according to one of claims 1 to 3, characterized in that the pig diameter D is dimensioned such that the minimum pig diameter D(M,min) corresponds to the maximum internal diameter of the pipeline or the bend D(R,max). 5. Pipeline pig according to one of claims 1 to 4, characterized in that the outlet diameter d of a T-branch used in the pipeline is designed to be one nominal width smaller than the nominal width of the pipeline receiving the T-branch.