1. Field of the Invention
This present invention relates to the field of pipeline inspection and testing, and more specifically to the field of pipeline inspection using electronic testing apparatus.
2. Discussion of the Prior Art
It is sometimes necessary to periodically inspect gas, oil, water and other metal pipelines for cracks, weakened spots, wall thinning, and other abnormalities caused by wear, trauma and/or corrosion. These typically are inspected using currently known electronic testing techniques, such as a magnetic flux leakage technique. The magnetic flux leakage technique is more fully explained in “Intelligent Pig Inspection of Uncoated Seamless Pipelines” by Terry R. Shamblin, Columbia Gas Transmission, Charleston, W. Va. in the March 200 issue of Pipeline and Gas Journal, and in “Research on Intelligent Pipeline Flux Leakage Detector” by Yang-Lijian and Wong-Yumei from the School of Information Science and Engineering, Shenyang Univ. Of Technology, Shenyang, China, hereby incorporated by reference as if set forth in their entirety herein. In this technique, conductive brushes each having a conductive base mounted around the perimeter of a hub, are rotated as they are passed through the inside of a pipeline. A magnetic source passes magnetic flux through the hub, through the base of the brushes and through the bristles. The bristles are brushed against the inner walls of the pipeline, thereby passing magnetic flux into the metal pipeline walls.
A magnetic flux measuring device having a number of magnetic sensors, follows closely behind the inspection brush on or near the pipeline inner surface and reads the remaining magnetic flux. The difference in the magnetic flux induced by the brushes and the readings from the magnetic sensors results in a measure of magnetic flux leakage for each location inside of the pipe. The magnetic flux leakage is related to pipe thinning, pipe weakening, pipe corrosion and other abnormalities. The magnetic flux leakage test therefore is an efficient test for abnormalities of a metal pipeline.
The inspection brush is comprised of a plurality of elongated pencil end brushes, having conductive metal bristles extending from a base cup. These prior art pencil end brushes are typically constructed having metal bristles, usually steel, that are soldered into a base cup. The base cup is connected to a magnetic source and is designed to pass magnetic flux from the magnetic source, to the bristles, then from the bristles to the pipeline walls.
There are known prior art methods of constructing these pencil brushes. These include cutting the bristles to a specified length, inserting them into a cup and attaching to the cup with an attaching medium such as solder or epoxy. The open edge of the cup may or may not be crimped where the bristles enter the cup.
The prior art attachment methods are subject to failure where the bristles are not fully embedded in the attaching medium. Brush integrity requires that every bristle be fully in contact with the attaching medium. Partial contact with the medium results in reduced strength of the brush. It is difficult, if not impossible to assure that each bristle is in full contact and the only method of being certain of that is by a destructive disassembly of the brush.
During use of the inspection brush inside of the pipeline, bristles may be pulled out of or otherwise fall out of the brush or the entire brush may fall apart. The pieces will be dispersed throughout the system. This would cause great damage to the pipeline pumps, valves, seals and related equipment. It would also be a very costly and time consuming process to ‘fish’ all of the pieces.
Since nickel is a good electrical conductor and conducts magnetic flux very well, nickel plated bristles are preferred. The use of nickel plating would allow the testing process to be performed much more quickly and efficiently indirectly saving large amounts of money in ‘down time’ since the pipeline may not be used during the testing process. However, the attachment of nickel plated parts is not easily attached using solder or epoxy. This again results in reduced strength of the brush.
Another goal of the brush is to maximize electrical conductivity from the base housing to the bristles to the pipeline wall. Firm contact must be maintained between the base housing and the bristles to maintain high magnetic flux. Bristles that are held partially by solder or epoxy will have reduced contact and therefore reducing conductivity.
An alternate means of securing nickel plated bristles would be to position the bristles inside the base housing, then compress the upper edge of the base housing to crimp the bristles in place. This crimping alone results in a weakened brush with low electrical conductivity.
Therefore, there currently is a need for a high magnetic testing brush which is very resilient and would not release bristles into the pipeline.
a, 7b, 7c and 7d illustrate a process for making a brush compatible with the present invention.
The present invention includes a resilient inspection brush for electronic inspection of pipelines, and method of constructing the same.
The invention employs a plurality of resilient pencil end inspection brushes each having increased magnetic flux capacity. These are constructed of a high flux material, and are constructed without the need for solder or epoxy. They are very resilient and will resist breakage and dismemberment when in use.
The resilient inspection brush includes an electrically conductive base housing having a generally cylindrical shape with a bottom portion and a top portion. A recess passes generally through the base housing lengthwise from top to bottom. The bottom may be enclosed to make a cup shape.
A retaining member is secured in, or near the bottom of the base housing and extends in a direction generally perpendicular to the length of the recess, passing at least partially across the recess.
A number of electrically conductive bristles are tightly packed into the base housing. Each bristle has at least a first end, a second end and a securing portion between the first and second ends. The securing portion of each bristle at least partially encircles the retaining member, with the end portions extending out of the top of the base housing.
The present invention also includes a method for constructing the resilient inspection brush.
First, an electrically conductive base housing is provided having a generally cylindrical shape, a bottom portion, a top portion and a recess passing generally lengthwise from the top to bottom portions.
Next a number of bristles are formed.
The number of bristles are positioning in a generally parallel configuration across the top of the base housing such that they are generally perpendicular to the length of the recess.
The elongated retaining member is positioned across the bristles.
And the retaining member is forced into the recess, thereby folding the bristles into the recess such that they are held in place by the retaining member.
Optionally, the top of the base housing may be swedged to further hold the bristles in place.
The bristles may be made of different materials and tempered or untempered, plated, coated or uncoated of virtually any desired diameter.
Prior art inspection brushes have individual bristles which were soldered, epoxied, or otherwise glued into the base housing. These do not exhibit the electrical conduction properties and strength exhibited by the present invention. These properties are very important since pieces of the inspection brushes which break off can destroy pipeline equipment, make it unusable for a period of time and may be very expensive to repair.
Similarly, other bristles such as bristle 333 also have a first end 333a, a second end 333b, and a securing portion 333c.
The bristles for the brushes may be wire that is tempered or untempered, plated, coated or uncoated in virtually any desired diameter. These wires should be electrically conductive. A number of bristles are packed into base housing 320, thereby causing a tight fit, securing them into the base housing.
The unique configuration of the base housing 320 allows it to retain the substantially straight sides desired by the end users while firmly holding the bristles in the base housing and maintaining tight contact between all of the bristles and the base housing for excellent conductivity.
To further secure retaining member 350 inside base housing 320 and to further secure bristles 331, 333, etc. the top portion 321 of base housing 320 is “swedged” by crimping or compressing top portion 321 into a smaller diameter, physically pressing against the bristles.
Retaining member 350 may be implemented by using a rod slightly shorter than the internal diameter of base housing 320. If the retaining member 350 is implemented in this manner, swedging base housing 320 after retaining member 350 has been inserted into base housing 320, secures retaining member 350 inside of base housing 320, since it is now too large to pass through the smaller opening in the top portion 321 of base housing 320. (
Retaining member 350 may be secured by other known means as long as the electrical conductivity between base portion 320, retaining member 350 and bristles 331, 333 are maintained.
In an alternative embodiment of the present invention, the securing portion 331c, 333c of bristles 331, 333 may be wound around securing device 350 several times as shown by the dashed lines shown in
A method of constructing the present invention is described below.
1. An electrically conductive base housing 320 is provided having a generally cylindrical shape, a bottom portion 325 and a top portion 321 with a recess 327 passing generally lengthwise from the top to bottom portions.
2. A number of bristles are formed.
3. The bristles 330 are positioning in a generally parallel configuration across the top of the base housing 320 such that they are generally perpendicular to the length of the recess 327 as shown in
4. An Elongated Electrically Conductive Retaining member 350 is then positioned across the bristles 330, as shown in
5. The retaining member 350 is forced into the recess 327, thereby folding the bristles 330 into the recess 327 such that they are held in place by the retaining member 350, as shown in
Since the bristles are held in place by the retaining pin, brush integrity is maintained.
In another embodiment, each of the bristles 330 are wound at least a full circle around the retaining member 350. The wires are wound before the retaining member 350 is inserted into the base housing 320.
Optionally, the top of the base housing 320 may be compressed in swedged section 340 to further hold the bristles 330 in place as shown in
Inner sleeve 810 has at least one catch 811, 813 on its outer surface which are designed to fasten easily to a corresponding groove(s) 861, 863 when inner sleeve 810 is inserted into central recess 880 in base housing 860. It can be seen that the catches are wedge-shaped moving from bottom to top, and have an abrupt shoulder 812, 814 at the uppermost edge thereby resisting release once fastened.
In
During assembly of the embodiments above, a solder or thermoplastic may be placed in the bottom (325 of
Other epoxies, glues, and adhesives may also be used to further strengthen the assembly.
This application claims priority from U.S. Provisional Patent Application 60/607,387 “RESILIENT PIPELINE INSPECTION BRUSH” filed Sep. 3, 2004 in which a portion of the information was originally filed whereas additional information is being filed in this application as a continuation-in-part application.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2005/031405 | 9/2/2005 | WO | 00 | 2/19/2007 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/029008 | 3/16/2006 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3839763 | Gould | Oct 1974 | A |
4408367 | Pusterhofer | Oct 1983 | A |
5445438 | Drumm | Aug 1995 | A |
6726789 | Weihrauch | Apr 2004 | B1 |
Number | Date | Country | |
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20070261186 A1 | Nov 2007 | US |
Number | Date | Country | |
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60607387 | Sep 2004 | US |