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Registered Member #1334
Joined: Tue Feb 19 2008, 04:37PM
Location: Nr. London, UK
Posts: 615
Is Koptan (a Kapton clone) any good - I see various comments in other (non-HV) forums saying its fine, but has anyone compared it with the real stuff and tried it in an HV environment?
NB. Its about 5x or 10x cheaper than the Dupont offering...
Registered Member #543
Joined: Tue Feb 20 2007, 04:26PM
Location: UK
Posts: 4992
I have bought polyimide tape from Chinese ebay sellers for use in ionisation chamber windows. I examined it with an optical microscope at x400 and found it to be mainly free of defects.
I do know that kapton enjoyed a brief heyday in avionics - brief because it was found to chafe through in cable looms.
Registered Member #531
Joined: Sat Feb 17 2007, 10:51AM
Location: Burlington, Vermont
Posts: 125
Proud Mary wrote ...
I do know that kapton enjoyed a brief heyday in avionics - brief because it was found to chafe through in cable looms.
I work for an aerospace company here in the states and I can tell you unequivocally that it is still widely used in our products.
The best part is that MIL-SPEC (or our own internal requirements, not sure which) dictates that it is unusable due to age after ~1 year so it is regularly scrapped.
Registered Member #543
Joined: Tue Feb 20 2007, 04:26PM
Location: UK
Posts: 4992
scott fusare wrote ...
Proud Mary wrote ...
I do know that kapton enjoyed a brief heyday in avionics - brief because it was found to chafe through in cable looms.
I work for an aerospace company here in the states and I can tell you unequivocally that it is still widely used in our products.
The best part is that MIL-SPEC (or our own internal requirements, not sure which) dictates that it is unusable due to age after ~1 year so it is regularly scrapped.
UNITED STATES NUCLEAR REGULATORY COMMISSION OFFICE OF NUCLEAR REACTOR REGULATION WASHINGTON, D.C. 20555
November 21, 1988
Information Notice No. 88-89: DEGRADATION OF KAPTON ELECTRICAL INSULATION
Addressees:
All holders of operating licenses or construction permits for nuclear power reactors.
Purpose:
This information notice is being provided to alert addressees to a potentially generic safety problem involving Kapton aromatic polyimide electrical insulation. Kapton is used extensively in nuclear power plants as wire insulation in con-tainment penetrations and cable entrance seals manufactured by Conax Buffalo Corporation, and in various insulation systems in products supplied by other vendors. Kapton is a registered trademark of E. I. du Pont de Nemours and Company.
It is expected that recipients will review the information for applicability to their facilities and consider actions, as appropriate, to avoid similar problems. However, suggestions contained in this information notice do not constitute NRC requirements; therefore, no specific action or written response is required.
Description of Circumstances:
Problems involving Kapton insulation have been reported at nuclear power plants and elsewhere as described below. The most significant event identified in the nuclear industry occurred at San Onofre Unit 1.
San Onofre Nuclear Generating Station Unit 1
On June 15, 1987 Southern California Edison Company advised the NRC of a problem involving damaged Kapton insulation on containment electrical penetration assemblies at San Onofre Unit 1. During electrical testing of control rod drive equipment circuits to determine if previous cooling fan malfunctions had caused any damage, unacceptably low insulation resistances were found on 35 circuits. In one penetration assembly alone, 11 circuits tested below one megohm and 11 others below 100 megohms. The licensee then visually inspected the approximately 5000 penetration leads in the plant, and discovered nicked insulation in 52 cables covering close to 200 circuits. Most of the defects were outside containment; 15 nicked leads were inside containment.
8811150088 . IN 88-89 November 21, 1988 Page 2 of 5
Laboratory analysis of two damaged leads showed no signs of electrically induced damage, and the insulation edges at the breaks were smooth (suggesting moderate chemical attack). The damage sites were highly localized; adjacent insulation showed no degradation. The copper conductor was oxidized considerably.
As a short-term corrective action, the licensee replaced all safety-related wires showing any signs of degradation or damage. Longer-term corrective action, now partially completed, includes provision of cable tray covers; replacement of nicked non-safety-related cables; and administrative and procedural measures such as personnel training and written precautions concerning unprotected Kapton-insulated wires. This event is described in Licensee Event Report 05000205 87-008-00, dated July 10, 1987.
The licensee attributed the damage primarily to physical damage (cuts, punc- tures, abrasions) to exposed Kapton insulation, mainly during installation of the replacement penetration assemblies in 1985-86. Some damage was attributed to subsequent stepping on the wires and placing or dropping objects on them. Once the Kapton insulation was penetrated, condensation of marine air on the outside containment pigtails provided a conductive path that lowered insulation resistances. The extensive replacement of containment electrical penetration assemblies such as occurred at San Onofre Unit 1 is uncommon, and it contributed to the exposure of unprotected Kapton leads to mechanical damage. Exposure of the Kapton leads to an outside marine atmosphere is also unusual.
Other Kapton Concerns
(1) Information Notice 87-08 (reference 1) describes 1986 failures of motorized valve operators because wires insulated with Kapton/Teflon and Nomex short-circuited. The Kapton/Teflon was a 0.0012-inch tape overlapped 50-percent. These wires were subjected to abrasion damage during wiring of the valve operators.
(2) Information Notice 87-16 (reference 2) describes 1987 degradation of Kapton diaphragms in pressure switches caused by chemical attack by ammonia con-tained in the process fluid.
(3) In 1984 Gulf States Utilities filed a 10 CFR 50.55(e) report concerning a short circuit between two Kapton-insulated wires from Conax penetration assemblies at River Bend Station Unit 1. The condition occurred during plant construction, and inspection showed 15 of 201 conductors to have nicked or otherwise damaged insulation. Investigation showed that degra- dation was generally attributable to scuffs, gashes, and related damage aggravated by the presence of water.
(4) In several instances anomalies have occurred during qualification type testing of Kapton-insulated pigtail wires on Conax products or on other equipment such as transmitters that had cable entrances sealed by Conax seals. The anomalies have been attributed to handling and stresses not typical of plant installations; e.g., shipment from a radiation test facility to a steam test facility. Only a few wires showed degradation in each instance, whereas multiple wires not subject to abnormal handling have successfully completed type test sequences.
. IN 88-89 November 21, 1988 Page 3 of 5
(5) In response to Information Notices 87-08 and 87-16, du Pont wrote to the NRC to caution that when Kapton is used in nuclear power plants where environmental qualification is required, engineered designs which protect Kapton from direct exposure to loss of coolant accident sprays are required. This is because Kapton tends to degrade when exposed to high temperature steam or to certain volatile chemicals such as sodium hydroxide.
(6) The Naval Research Laboratory (NRL) has published or presented several papers (references 3, 4) describing failures of Kapton-insulated wires during laboratory testing. The Navy has carefully examined potential problems with Naval aircraft service. As a result, The Navy intends to stop buying aircraft using Kapton-insulated wire, and the other military services are studying possible implementation of restrictions.
The NRL work, in conjunction with other available information, shows that Kapton wire insulation is subject to damage by four mechanisms:
ø Mechanical nicking or gouging can expose a wire conductor. Low in- sulation resistance can occur if an electrical path to an adjacent metallic conductor is formed by either a conductive solution or direct metal-to-metal contact. The San Onofre Unit 1 event is of this type.
ø Direct chemical attack by strong alkaline solution can dissolve Kapton. This process would be of concern only if Kapton were installed contrary to Conax installation instructions in plants with sodium hydroxide spray, so that the Kapton was either exposed to prolonged direct spray impingement or prolonged soaking in spray solution.
ø Bullets or projectiles can damage energized wire bundles. This is not likely in commercial power plants, and related safety concerns are minimal because of the redundancy and separation used for safety-related equipment.
ø A complex hydrolytic Kapton degradation process has been identified with synergistic, non-linear dependence on temperature, moisture, and mechanical strain. Test data from 60 degrees Celsius upward show a reciprocal logarithmic temperature dependence. du Pont (reference 5) has suggested a fifth-power humidity dependence. Wolf (reference 6) reported a strong dependence on strain and postulated a minimum strain of 3 to 4 percent below which degradation does not occur. The process is almost fully reversible provided that actual cracking has not occurred. Review of commercial nuclear power plant applications indicates that this mechanism is not significant for either normal or accident conditions; operating experience and type test results support this conclusion. However, violation of minimum bend radius requirements specified by Conax and Rosemount for their wires, combined with significant moisture exposure and elevated temperatures, could produce this type of damage.
. IN 88-89 November 21, 1988 Page 4 of 5
du Pont has several publications describing Kapton and its use. These may be obtained by contacting:
Mr. Paul Wyche E. I. du Pont Nemours and Company, Inc. External Affairs Department N-2526 Wilmington, Delaware 19898 Phone: (302) 774-1942
Conax Seals
The major safety-related use of Kapton in commercial nuclear power plants is in Conax products: containment electrical penetration assemblies, penetration replacement adapter module assemblies, electrical conductor seal assemblies (ECSAs), PL-type gland seals, and resistance temperature detector assemblies. Conax uses Kapton-insulated wire constructed of two wraps of type FN Kapton film, spiral wrapped in opposite directions. Since the film consists of 0.001 inch of Kapton sandwiched between two 0.0005-inch layers of Teflon (a du Pont trademark for FEP fluorocarbon), and each wrap is overlapped 50-percent, the total insulation thickness is 0.008 inch. The MIL-W-81381/11 wire used by the Navy is similar except that it has a 0.002-inch dispersed Kapton topcoat.
For seal assemblies, Conax supplies a heat-shrinkable polyolefin jacket to me- chanically protect Kapton insulation. In addition, installation manuals caution against mechanical damage and protective conduit is also specified. Penetration assemblies are supplied with a junction box which encloses Kapton leads. Most other vendors using Kapton-insulated leads in safety-related applications provide covers or enclosures (for example, Rosemount seals and Target Rock and Valcor solenoid valves).
Discussion:
Despite the plant-specific aspects of the San Onofre Unit 1 event, the generic lesson is that the performance of numerous Kapton-insulated wires degraded considerably after only one year in a quite mild environment. Mechanical damage to Kapton insulation combined with exposure to condensation of moist salty air produced unacceptable degradation of the electrical insulation properties.
Although Kapton-insulated pigtails have successfully completed several accident qualification type tests, the test specimens are believed to have been free from nicks in the insulation; further, test anomalies occurred in some cases in which the pigtails were subjected to abnormal handling. The lesson is that preaccident damage can lead to failure of Kapton-insulated wires during or after accidents.
Addressees are alerted that the following conditions may breach the integrity of Kapton insulation, leading to possible failures under either normal or accident conditions:
(1) Mechanical damage such as nicks, cuts, abrasion, or sharp bending combined with exposure to moisture.
(2) Prolonged contact with alkaline solutions. . IN 88-89 November 21, 1988 Page 5 of 5
Addressees are also reminded that excessive handling of wiring is undesirable. In view of the industry's generally good operating experience with Kapton, addressees may elect to take actions in response to the information in this notice by beginning with review of procedures and designs to determine whether the conditions cited above may exist. Caution with any future maintenance or installation activity involving Kapton is important.
Virtually all commercial nuclear power plants contain Kapton-insulated wires in safety and non-safety-related applications, with Conax products used most extensively. Such components as containment electrical penetration assemblies and cable entrance seals are commonly used in Class 1E circuits and in applications requiring qualification to 10 CFR 50.49. Failure of Kapton insulation during either normal plant operation or accident conditions could render associated equipment inoperable.
No specific action or written response is required by this information notice. If you have any questions about this matter, please contact the technical contact listed below or the Regional Administrator of the appropriate regional office.
Charles E. Rossi, Director Division of Operational Events Assessment Office of Nuclear Reactor Regulation
Technical Contact: Richard C. Wilson, NRR (301) 492-0997
Attachments: 1. References 2. List of Recently Issued NRC Information Notices . Attachment 1 IN 88-89 November 21, 1988
REFERENCES
1. Information Notice No. 87-08: "Degraded Motor Leads in Limitorque dc Motor Operators," February 4, 1987.
2. Information Notice No. 87-16: "Degradation of Static "O" Ring Pressure Switches," April 2, 1987.
3. F. J. Campbell, "Temperature Dependence of Hydrolysis of Polyimide Wire Insulation," IEEE Transactions on Electrical Insulation, Vol. EI-20 No. 1, February 1985.
4. A. M. Bruning, "Predictive Life Measurements of Naval Aircraft Wiring," Proceedings: Workshop on Power Plant Cable Condition Monitoring, EPRI EL/NP/CS-5914SR, July 1988.
5. J. O. Punderson and J. F. Heacock, "Polyimide Film Insulation for Aerospace Wire and Cable: Why Long-Term Performance Exceeds Some Limited Laboratory Projections, " presented at the 34th International Wire and Cable Symposium, Cherry Hill, NJ, November 19-21, 1985 (available from du Pont).
6. C. J. Wolf, D. L. Fanter, and R. S. Soloman, "Environmental Degradation of Aromatic Polyimide-Insulated Electrical Wire," IEEE Transactions on Electrical Insulation, Vol. EI-19 No. 4, August 1984. . Attachment 2 IN 88-89 November 21, 1988 Page 1 of 1
Concerns About Kapton Wiring Raised Two Decades Ago
Kapton (aromatic polyimide) is the dominant form of general purpose wire insulation on a number of aircraft in service, notably the Swissair MD-11 that crashed Sept. 2, and also including the DC-10, MD-80, 727, 737 (current generation), 747-100/200/300, and the 767. It has a long and controversial history, and the industry has since opted for improved insulation types, such as Teflon-coated Kapton (see ASW, Sept. 21).
However, thousands of miles of Kapton wire are found in older jetliners still in service. One wire and cable expert believes the FAA should require improved wiring types (such as TKT) for all repair replacement wiring and for wiring included in modification kits. Below, a letter sent two decades ago from TWA's director of electronics engineering to Boeing, saying the airline did not want to receive any more new jets outfitted with Kapton wiring:
June 30, 1977
Mr. Jack Miller
727 Customer Engineering, Boeing Commercial Airplane Co. Seattle, Washington 98241 Subject: General Purpose Airframe Electrical Wire
Dear Jack:
An informal meeting of Boeing and TWA wire specialists was held at Renton on June 21, 1977. It was learned from this discussion that Kapton insulated wire is the prime candidate as a replacement for PVC/Nylon general purpose airframe on the B727.
We are concerned about such an application because of our experience with Kapton insulated wire on the L-1011. As brought out in the meeting, wire failures are not excessive in terms of absolute numbers, but the mode of failure has put some of our aircraft out of service for one to three days, and in one case triggered extensive fire damage...
We have found that a wire-to-wire or wire-to-ground short circuit can occur if the insulation is nicked or pinched, because Kapton insulation inherently allows the surface damage to propagate to the conductor. When an arc is struck, the tough, high-temperature insulation material does not flow, causing the molten copper to spew out of the small fault in the insulation and damage the insulation of adjacent wires. The damage and short circuits progress successively through the bundle until all or most of the bundle are severed.
Also...Kapton wire will further aggravate the problems of bent and pushed back contacts and moisture contamination experienced with...connectors. The most extensive application of Kapton wire has been on the L-1011 which uses MIL-C-83723 Type III connectors that feature closed entry contacts and improved moisture seals. This connector is more forgiving when confronted with the springiness and spiral wrap of Kapton wires, which tend to splay the contacts and reduce moisture seal effectiveness. Despite the efforts of TWA and other airlines to switch to MIL-C-83723 connectors, the B727 still incorporates MIL-C-26500 connectors in the basic design.
Another potential problem we foresee is one that could result from attempting to bring down the cost of Kapton insulated wire to make it competitive with other wire constructions. We understand that wire manufacturers now claim to have a method to process the wire that will permit tin coated conductors to be used. Silver or nickel coated conductor is presently used because of the high temperature required to fuse the Kapton/FEP film wrap. Kapton insulated wire would be highly vulnerable to conductor strand blocking if tin coated conductors are used. This blocking would result in insidious problems of conductor breakage to plague the airlines.
Because of Kapton's notch sensitivity and other minus factors such as springiness, delamination, difficulty in stripping and cost, we will strongly object to any proposed use of this wire on future TWA aircraft.
Very truly yours, W.B. Clark Director - Electronics Engineering
Registered Member #531
Joined: Sat Feb 17 2007, 10:51AM
Location: Burlington, Vermont
Posts: 125
Interesting, but it does not change the fact that material is still used in the aerospace community. I'll ask around and see what the story is from our end.
Registered Member #3040
Joined: Tue Jul 27 2010, 03:15PM
Location: South of London. UK
Posts: 237
I can't remember where, but I saw a video of a Kapton wiring fire in a Lab based controlled experiment YEARS ago. Best I can find on the WEB is but I saw it before 2008. The videos on this link don't work for me but that may be because I'm UK based? If they work for anyone else let me know.
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Kapton vs. Koptan - polyimide tapes?
