RU125901U1 - INDOOR PISTON - Google Patents

Abstract

1. An in-piston piston having an axis of symmetry, containing adjacent piston elements, tightened together by couplers located away from the axis of symmetry of the piston, characterized in that at least one of the piston elements has a through hole through which passes the axis of symmetry of the piston, the specified hole forms a cavity in the piston, the cavity is made capable of deformation. 2. The intra-piston piston according to claim 1, characterized in that the screed is made in the form of a clamp, wrapping around at least one element of the piston and pressing it against adjacent elements. The intra-piston piston according to claim 1, characterized in that the screed presses the piston element forming the first end of the piston to the adjacent piston elements in the direction of the second end of the piston, the same screed compresses the piston element forming the second end of the piston to the adjacent piston elements in direction of the first end of the piston. 4. The intra-piston piston according to claim 1, characterized in that through-holes are made in the piston elements through which the axis of symmetry of the piston passes, said holes form a cavity in the piston, at least one plug is installed in the cavity, overlapping the cavity section so that the region the space on one side of the stub does not communicate with the area of space on the other side of the stub. 5. The intra-piston piston according to claim 1, characterized in that the piston also contains a source of magnetic and / or electromagnetic field, at least one of the piston elements has a through hole through which the axis of symmetry of the piston passes, said hole forms a cavity in the piston, cavity mounted source

Description

The utility model relates to devices for cleaning the cavity of pipelines, mainly, trunk and field pipelines, gas pipelines and oil pipelines.

Known in-line piston (RF patent for utility model RU 64536, publication date 07/10/2007, IPC B08B 9/055) having a symmetry axis containing adjacent to each other piston elements. The piston is characterized in that the piston elements are made of rubber or polyurethane.

A tubular piston is known (US patent US 6014789, publication date 01/18/2000, IPC B08B 9/04) having an axis of symmetry containing adjoining piston elements pulled together by a coupler located along the axis of symmetry of the piston.

The main disadvantage of these piston options is the limited patency of the piston through the narrowing section of the pipeline due to the lack of a cavity in the piston body.

A tubular piston is known (European patent EP1293266, publication date 02/28/2007, IPC B08B 9/055) having an axis of symmetry containing adjoining piston elements pulled together by couplers located away from the axis of symmetry of the piston. The piston is characterized in that through holes are made in the piston elements through which the axis of symmetry of the piston passes. Through these holes passes a metal casing having an undeformable cavity. The passage of the specified piston through the narrowing section of the pipeline is also limited due to the non-deformability of the cavity in the housing in the piston body.

The prototype of the claimed utility model is an in-line piston (patent of the Russian Federation for utility model RU 105847, publication date 06/27/2011, IPC BVB 9/055), having an axis of symmetry containing adjoining piston elements pulled together by ties located to the side of the axis piston symmetry. The piston is characterized in that the couplers are made in the form of tubes. A disadvantage of such a piston is also the limited piston throughput through the narrowing of the pipeline section due to the absence of a cavity in the piston body.

An in-line piston is also claimed, also having an axis of symmetry, containing adjoining piston elements pulled together by couplers located away from the axis of symmetry of the piston.

The claimed in-piston piston differs from the prototype in that at least one of the piston elements has a through hole through which the axis of symmetry of the piston passes, said hole forms a cavity in the piston, the cavity is capable of deformation.

The main technical result obtained as a result of the implementation of the utility model is that the presence of a cavity in the piston allows to increase the patency of the piston through the narrowing in the cross section of the pipeline through which the piston is passed.

In one embodiment of the utility model, the screed is made in the form of a clamp wrapping around at least one element of the piston and pressing it against adjacent elements.

In another embodiment of the utility model, the coupler presses the piston element forming the first end of the piston to the adjacent piston elements in the direction of the second end of the piston, while the same coupler presses the piston element forming the second end of the piston to the adjacent piston elements in the direction of the first end of the piston.

In development of a utility model:

through holes are made in the piston elements through which the axis of symmetry of the piston passes, these holes form a cavity in the piston, at least one plug is installed in the cavity, overlapping the cavity section so that the space region on one side of the plug does not communicate with the space region c the other side of the stub;

the piston also contains a source of magnetic and / or electromagnetic field, at least one of the elements of the piston has a through hole through which the axis of symmetry of the piston passes, said hole forms a cavity in the piston, a source of magnetic and / or electromagnetic field is installed in the cavity;

at least one of the piston elements is made in the form of a disk of material capable of plastic deformation;

at least one of the elements of the piston is made in the form of a disk of metal;

part of the piston elements is made in the form of plates capable of plastic deformation, the plates are mounted radially relative to the axis of symmetry of the piston;

some of the piston elements are made in the form of metal brushes capable of contact with the inner surface of the pipeline when the piston is placed in it.

In one embodiment, at least one of the screeds is made of a polymeric material.

In another embodiment, at least one of the couplers is made in the form of a tube made of a polymer material, or

at least one of the ties is made in the form of a rod or fishing line or wire or cable or rope or rope.

In the further development of the utility model:

at least one of the piston elements is made of plastic or caprolon;

at least one of the piston elements is made in the form of a non-circular cylinder;

at least one of the piston elements is made in the form of a cuff, a part of the outer surface of which is made in accordance with the condition according to which the outer diameter of the cuff increases as the cross section of the cuff moves away from the end of the piston, which serves as the front end when passing the piston inside the pipeline;

at least one of the piston elements is made of a polymeric material, the shore hardness of which is at least 90;

at least two piston elements are made in the form of elastic elements made of a polymeric material in the form of disks or cuffs, at least one of the piston elements is made in the form of a polymer spacer, at least between said two elastic elements one specified polymer spacer, Shore hardness of the material of said elastic elements is 10-70 units less than the Shore hardness of the material of said polymer spacer;

at least one of the piston elements is made in the form of a petal element in the form of a disk or cuff with cuts in the form of sectors on the periphery of the petal element, so that petals are formed between the cuts;

some of the piston elements are made in the form of at least one pair of petal elements made in the form of discs or cuffs with cuts in the form of sectors on the periphery of the petal element, so that petals are formed between the cuts, each petal element in a pair is rotated relative to the second petal element in pair around its axis of symmetry so that the cut-out area of one petal element in the pair coincides with the petals of the second petal element in the pair, and the cut-out area of the second petal element in the pair coincides t with the petals of the first petal element in pair.

Figure 1 shows a General view of the piston in one embodiment, in which the screed is made in the form of a clamp;

figure 2 shows the piston shown in figure 1, in section;

figure 3 shows one of the embodiments of the piston, in which the screed is made in the form of a curved rod;

figure 4 shows a coupler in the form of a curved rod;

figure 5 shows one of the embodiments of the piston, in which the screed is made in the form of a rod, and one of the elements of the piston is made in the form of a cuff.

Figure 1, figure 2 shows the in-line piston in one embodiment. The piston has an axis of symmetry 100, contains adjacent piston elements 101, 102, pulled together by ties 103, 104, located away from the axis of symmetry 100. In each of the piston elements 101, 102 there is a through hole 105, 106, respectively, through which passes the axis of symmetry 100, the holes 105, 106 form a cavity in the piston that is capable of deformation (the dimensions of the cavity change when the elements 101, 102 are deformed. Each of the couplers 103, 104 is made in the form of a clamp wrapping around two piston elements 101 and 102 and presses the element 101 to element 102, and the element 102 to element 101. Couplers 103, 104 may be made of metal, at least one of the couplers may be made of polymer material, Each of couplers 103, 104 may be made in the form of a tube or fishing line or wire or cable or rope or In another embodiment, at least one of the couplers is made in the form of a tube of polymeric material.

The piston also contains a source 107 of low-frequency electromagnetic field (preferably 22 Hz), which is installed in the cavity; in addition to, or instead of, the source of the electromagnetic field 107, a plug may be installed in the cavity, overlapping the section of the cavity so that the space region on one side of the plug does not communicate with the space region on the other side of the plug. In a preferred embodiment, the piston elements 101, 102 are made of plastic, caprolon or polyurethane. The Shore hardness of the material of elements 101, 102 is at least 90.

Figure 3 shows the in-line piston in another design. The piston has an axis of symmetry 200, contains adjacent to each other piston elements 201-215, pulled together by couplers 221, 222, located away from the axis of symmetry 200. A through hole is made in each of the piston elements 201-215 through which the axis of symmetry 200 passes , these holes form a cavity 220 in the piston that is capable of deformation (the dimensions of the cavity change upon deformation of at least part of the elements 201-215. Each of the couplers 221, 222 is made in the form of a rod with a bend of 180 degrees in its middle, so that both ends of the rod are located wrenches from one end of the piston.

Each of the couplers 221, 222 presses the piston cone element 201, forming the first piston end, to the adjacent piston elements 202-215 in the direction of the second piston end, which is formed by the flange element 215, while the same coupler presses the flange 215 against the neighboring elements 201- 214 of the piston in the direction of the first end of the piston formed by the cone element 201. The nuts at the ends of the couplers 221, 222 provide a clamping of the elements 201-214 to the flange 215, some of the nuts (223, 224) are shown in FIG. 3. Ties 221, 222 can be made of metal, at least one of the screeds can be made of polymeric material. Each of the ties 221, 222 can be made in the form of a tube or fishing line or wire or cable or rope or chain.

Each of the piston elements 208, 212 is made in the form of a metal disk capable of plastic deformation; alternatively, instead of a disk, a set of plates capable of plastic deformation can be installed, plates can be installed radially relative to the axis of symmetry of the piston. In another alternative embodiment, the element 208 and / or 212 may be made in the form of metal brushes capable of contact with the inner surface of the pipeline when a piston is placed in it.

The piston elements 201, 202, 204, 206, 207, 209, 211, 213 are made of plastic or caprolon or rigid polyurethane. The Shore hardness of the material of the indicated elements 201, 202, 204, 206, 207, 209, 211, 213 of the piston is at least 90. The elastic elements 203, 205, 210, 214 of the piston are made in the form of discs made of soft polyurethane. Elements 204, 206, 207, 209, 211, 213 form polymer spacers between disks 203, 205, 210, 214. The Shore hardness of the material of said elastic elements 203, 205, 210, 214 is 10-70 units less than the Shore hardness the material of these polymer spacers. These spacers are made in the form of round cylinders, in an alternative design, the spacers can be made in the form of non-circular cylinders.

In order to pass a piston inside a pipeline consisting of pipes of various nominal diameters, at least one of the piston elements can be made in the form of a petal element in the form of a disk or cuff with cutouts in the form of sectors on the periphery of the petal element, so that petals are formed between the cutouts; in a preferred embodiment, some of the piston elements are made in the form of at least one pair of petal elements made in the form of discs or cuffs with cuts in the form of sectors on the periphery of the petal element, so that petals are formed between the cutouts, each petal element in a pair is rotated relative to the second a petal element in a pair around its axis of symmetry so that the cut-out area of one petal element in a pair coincides with the petals of the second petal element in a pair, and the cut-out area of the second petal ovogo element paired coincide with the petals of the first tab member in the pair.

The piston also contains a source 227 of a low-frequency electromagnetic field (preferably 22 Hz), which is installed in the specified cavity in the piston; in addition to or instead of the electromagnetic field source 227, a plug 228 can be installed in the cavity, overlapping the cavity section so that the space region on one side of the plug 228 does not communicate with the space region on the other side of the plug 228, as well as the plug 229, overlapping the cavity section so that the area of space on one side of plug 229 does not communicate with the area of space on the other side of plug 229. A bracket 230 is installed at the front of the piston for storing the piston in the pipeline.

Figure 5 shows the in-line piston in another design similar to the piston shown in figure 3. The piston of FIG. 5 has an axis of symmetry 300, contains adjoining elements pulled together by ties 321, 322, located away from the axis of symmetry 300. In each of the piston elements there is a through hole through which the axis of symmetry 300 passes, these holes form in the piston, a cavity 320 capable of deformation, in which a source 327 of a low-frequency electromagnetic field is installed. Each of the couplers 321, 322 is made in the form of a rod with a bend of 180 degrees in its middle, so that both ends of the rod are located at one end of the piston. A feature of the piston shown in FIG. 5 is that the piston element 301 is made in the form of a cuff, a part of the outer surface of which is made in accordance with the condition that the outer diameter of the cuff increases as the cross section of the cuff moves away from the end face 302 of the piston serving as the front end when passing the piston inside the pipeline.

The device operates as follows.

The piston is placed in the storage chamber of the in-tube shells when the product is switched off by pipeline. After this, the product is pumped, which drives the piston and moves it first from the storage chamber into the pipeline, and then through the pipeline. In the pipeline, the piston moves until it is in the chamber for receiving in-tube shells. When the piston moves inside the pipeline, polymer disks or cuffs mounted on the piston fit snugly against the inner surface of the pipeline and provide a pressure differential between the area in front of the piston and the area behind the piston. Due to the specified pressure drop, the piston moves along the pipeline with the flow of the transported product. In addition, discs made of polymer material mounted on the piston clean off soft paraffin deposits, sand and debris from the inner surface of the pipeline. If metal brushes are installed on the piston, the latter can also remove solid asphalt-paraffin deposits from the pipeline’s inner surface.

A set of metal plates allows you to evaluate the bore of the pipeline. If during movement inside the pipeline the piston passes through a narrowing of the cross section, polymer disks, cuffs and metal brushes experience elastic deformation, due to which the piston passes through the narrowing. If there is a sufficiently significant narrowing of the cross section of the pipeline, then the polymer spacers also experience elastic deformation, ensuring the passage of the piston through significant narrowing of the cross section of the pipeline. At the same time, metal plates undergo plastic deformation and bend. If there was a narrowing of the cross section of the pipeline along the entire perimeter of the cross section and the diameter of the narrowing is less than the external diameter formed by the plates, all metal plates are bent. If, on the piston’s pass section, the narrowing of the cross section is formed by a foreign object (for example, a welded electrode), an inset extending deep into the pipe or a dent, then only some metal plates are bent. After removing the piston from the receiving chamber, the nature of the curvature of the metal plates is analyzed taking into account the number of bent metal plates and a conclusion is made about the presence and nature of the narrowing of the pipeline section at the piston pass section. If several sets of metal plates are installed, so that each set forms a different external diameter, then judging by the presence of curved metal plates in each set, in what range is the narrowing of the pipeline section.

The source of a low-frequency electromagnetic field during the movement of the piston inside the pipeline emits electromagnetic signals that are received outside the pipeline by the receiver of electromagnetic signals and, based on their presence, draw conclusions about the passage of the piston near the receiver of electromagnetic signals over a period of time.

Claims (19)

1. An in-piston piston having an axis of symmetry, containing adjacent piston elements, tightened together by couplers located away from the axis of symmetry of the piston, characterized in that at least one of the piston elements has a through hole through which passes the axis of symmetry of the piston, the specified hole forms a cavity in the piston, the cavity is made capable of deformation. 2. The intra-piston piston according to claim 1, characterized in that the screed is made in the form of a clamp, wrapping around at least one element of the piston and pressing it to adjacent elements. 3. The in-piston piston according to claim 1, characterized in that the screed presses the piston element forming the first end of the piston to the adjacent piston elements in the direction of the second end of the piston, while the same scuff presses the piston element forming the second end of the piston to the adjacent elements the piston in the direction of the first end of the piston. 4. The in-piston piston according to claim 1, characterized in that through-holes are made in the piston elements through which the axis of symmetry of the piston passes, said holes form a cavity in the piston, at least one plug is installed in the cavity, overlapping the cavity section so that that the area of space on one side of the stub is not in communication with the area of space on the other side of the stub. 5. The in-tube piston according to claim 1, characterized in that the piston also contains a source of magnetic and / or electromagnetic field, at least one of the piston elements has a through hole through which the axis of symmetry of the piston passes, said hole forms a cavity in the piston , a source of magnetic and / or electromagnetic field is installed in the cavity. 6. The in-line piston according to claim 1, characterized in that at least one of the piston elements is made in the form of a disk made of a material capable of plastic deformation. 7. The in-line piston according to claim 1, characterized in that at least one of the piston elements is made in the form of a metal disk. 8. The in-tube piston according to claim 1, characterized in that some of the piston elements are made in the form of plates capable of plastic deformation, the plates are mounted radially relative to the axis of symmetry of the piston. 9. The in-line piston according to claim 1, characterized in that some of the piston elements are made in the form of metal brushes capable of contact with the inner surface of the pipeline when the piston is inserted into it. 10. The in-line piston according to claim 1, characterized in that at least one of the couplers is made of a polymer material. 11. The in-line piston according to claim 1, characterized in that at least one of the couplers is made in the form of a tube made of a polymer material. 12. The in-line piston according to claim 1, characterized in that at least one of the couplers is made in the form of a rod, or fishing line, or wire, or cable, or tow, or chain. 13. The in-line piston according to claim 1, characterized in that at least one of the elements of the piston is made of plastic or caprolon. 14. The in-line piston according to claim 1, characterized in that at least one of the elements of the piston is made in the form of a non-circular cylinder. 15. The in-piston piston according to claim 1, characterized in that at least one of the piston elements is made in the form of a cuff, part of the outer surface of which is made in accordance with the condition according to which the outer diameter of the cuff increases as the cross section of the cuff is removed from the end face of the piston, which serves as the front end when passing the piston inside the pipeline. 16. The intra-piston piston according to claim 1, characterized in that at least one of the piston elements is made of a polymer material, the Shore hardness of which is at least 90. 17. The intra-piston piston according to claim 1, characterized in that at least two piston elements are made in the form of elastic elements made of polymer material in the form of disks or cuffs, at least one of the piston elements is made in the form of a polymer spacer wherein at least one of said polymer spacers is installed between the two said elastic elements, the Shore hardness of the material of said elastic elements is 10-70 units less than the Shore hardness of the material of said polymer spacer. 18. The intra-piston piston according to claim 1, characterized in that at least one of the piston elements is made in the form of a petal element in the form of a disk or cuff with cuts in the form of sectors on the periphery of the petal element, so that petals are formed between the cuts. 19. The in-piston piston according to claim 1, characterized in that some of the piston elements are made in the form of at least one pair of petal elements made in the form of discs or cuffs with cutouts in the form of sectors on the periphery of the petal element, so that between the cutouts are formed the petals, each petal element in the pair is rotated relative to the second petal element in the pair around its axis of symmetry so that the cut-out area of one petal element in the pair coincides with the petals of the second petal element in the pair, and the region in cuts in the second pair of the tab member coincides with the petals of the first tab member in the pair.

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