Description of High-Temperature Aircraft Electrical Wires

Descriptions of High-Temperature Aircraft Electrical Wire Types.

Left to themselves, things tend to go from bad to worse

Type	Properties	SOME Aircraft Used In
PVC/NYLON	Heaviest and thickest at 6.8 lbs. per 1,000 ft. Insulation burns readily creating copious smoke (e.g., ValuJet 592) *Insulation turns to hydraulic acid when exposed to water.	Early DC-9s, 727s, 737s until 1979
Poly-X (Aliphatic Polyimide)	The first exotic blend of insulation (due to Arab oil embargo) Light weight, 4.7 lbs. per 1,000 ft. Susceptible to solvents Chafing resistant but cracks around Circumference Copious smoke Due to brittleness, 1" bare spots not uncommon * premature aging at just 4,000 hrs * Fails FAR 25	Early 747s and DC-10s (e.g., TWA 800)
XL Tefzel *(Spec 55)	Copious smoke, density greater than 96% Cracks easiest under vibration (ETEF Type) * Toxicity the worst (ETE Type) * Arc tracks * Soft as butter at rated 150 degrees C – not 200 C * Must not be mixed in bundles with harder insulations. * Explodes in oxygen-enriched areas * Fails FAR 25	747s, 767s, 777s years? (mixed bundles found in SR111 IFE system)
Stilan	Light weight, 4.7 lbs. per 1,000 ft Insulation breaks down in hydraulic and de-icing fluid Microscopic crazing problem seen by microscope Cracks under stress Found to arc over Spurious signal generation * Fails FAR 25	747s and DC-10s built in mid-to-late 1970s
Kapton (Aromatic Polyimide)	Very light weight, 4.5 lbs per 1,000 ft Insulation burns fiercely creating no smoke Known to arc over Burns fiercely with arc over * Fails FAR 25	727s, 737s, some 747s(400s) 767s, DC-10s MD-80, MD-11, and A300-600 (with teflon top coat)
TKT	Light weight, 5.0 lbs. in per 1,000 ft. Abrasion resistant Superb insulation protection High heat tolerance *Resists smoking when burning (less than 2% density)	737s and 757s built late 1992 and on *Used on some aircraft since 1992.

Wednesday, January 20, 1999
The Halifax Herald Limited

Food, games 'stress' on Flight 111 wiring

By Stephen Thorne / The Canadian Press

Ottawa - Food and entertainment played critical roles in the Flight 111 disaster off Nova Scotia, conclude experts who say the timing of the plane's cockpit smoke points to the cause of the crash.

An hour into the Swissair flight, attendants aboard the doomed jet would have just turned on the plane's microwave ovens as they prepared meals for their transatlantic passengers, say aviators
and industry experts.

Many passengers, in turn, would be switching on their inflight entertainment systems - watching movies, listening to music, playing video games and gambling.

"Your maximum power requirements were being utilized at that time," said Patrick Price, a retired Boeing technician.

"If any circuit is under-protected - if it's not designed properly or the wrong gauge of wiring is used - that would put a greater stress on it. If you have an injured wire ... this is when it's most vulnerable."

Further stress on already-damaged wires could have been caused by the rigours of takeoff - vibration and other system demands - or rough weather. It was stormy the night the plane went down Sept. 2, killing 229 people.

"You've probably got this wire hanging by a thread," said Armin Bruning, a PhD in insulation systems design and head of Lectrical Mechanical Design Co. outside Washington, D.C.

"Now you put a little more load on it ... so it gets hotter, plus you agitate it physically more in this first hour. It's the time when that thread is most probably going to be subjected to stress and break."

Ed Block, member of a U.S. federal committee on aircraft wiring, concurred.

"That's certainly when you're going to get the maximum draw and anything waiting to happen is going to have its ignition point at that time," Block said from his home in Pennsylvannia. "It's the most likely time frame."

Some experts believe excessive handling of the MD-11's sensitive Kapton-insulated wiring may have contributed to the jet's problems.

Kapton, or aromatic polyimide tape, was effectively banned by the U.S. military due to its propensity to crack, chafe or break down with age.

McDonnell-Douglas also found that with vibration from flight Kapton tended to sandpaper away softer insulations like the one used in a high-tech entertainment system that Swissair installed early last year.

Even microscopic insulation deficiencies can lead to electrical arcing and flashovers, or lightning-like jumps between wires and wire bundles.

Canadian investigators have discovered such damage among burnt wire insulation aboard Swissair Flight 111 and over a dozen other MD-11s they looked at. Their findings prompted their U.S.
counterparts to request regulators to demand an urgent inspection of all 174 MD-11s worldwide.

A retired pilot who used to fly transatlantic routes for a European-based airline agreed that microwaves and entertainment systems would be coming on between 45 and 90 minutes into such
a flight.

But he noted that most pilots "don't normally concern themselves" with what demands are placed on their aircrafts' electrical systems.

"We never thought about maximum points of electrical load or anything like that until this latest incident with Swissair," said the ex-pilot, who did not want to be identified.

"Our job was more to fly the aircraft and do the management from the cockpit," he said. "What went on in the cabin with regards to the ovens being turned on and the inflight entertainment was really not our business."

Block said that's just the problem with the airline industry and the Swissair crash in particular - the pilots don't know their own airplanes.

Had 111's pilots realized the gravity of their situation when they first smelled cockpit smoke at least 22 minutes before the crash, they might have saved 229 lives, he said.

Subject: Another SwissAir 111 type of incident (Mixed types of wire)
Date: Fri, 08 Jan 1999 11:09:27 -0800
From: "James A. Bergquist" <clittle@cari.net
To: PAPCECST@aol.com
CC: devans@phillips.com, polytech@att.net, omega@omegainc.com, MGoldfein@belo-DC.com,
EdwBlock@aol.com, jking1@mediaone.net, RWROLAND@aol.com, barry@corazon.com,
110456.3354@compuserve.com, tim.dobbyn@reuters.com, daleroach@webcom.com,
sampson@iinet.net.au, RCOULTHART@ninenet.com.au, Res.Gehriger@sfdrs.srg-ssr.ch,
timothyclark@compuserve.com,

Patrick,

Do you want a copy of that photo? (Bill Hough photo. -AW&ST 2/9/98)
At 01:48 PM 1/8/99 EST, PAPCECST@aol.com wrote:
David et al,
I received this from Jim Bergquist this morning. I knew about it but not all
of the details. It's a good thing that the captain made the decision to make
an emergency landing when he did, or we might have had another 111 crash over
the ocean.

The cardinal rule was broken: YOU DON'T MIX TYPES OF WIRES!!! How many
airlines and their maintenance mechnics know about this rule?? The 767 is
wired with X-LINK TEFZEL (Raychem's BMS 13-48 wire) but they mixed it with
KAPTON WIRE from the chiller. It would be interesting to find out, HOW MANY
AIRLINES HAVE KNOWLEDGE THAT YOU DO NOT MIX DIFFERENT TYPES OF WIRES?

In looking over the video tape that Swiss TV made, when I was interviewed, I
saw some wire bundles in an overhanging panel in a MD-11. They were blue
wires and they were DOUBLED OVER and held in that position with white plastic
ties. 111 was wired with KAPTON WIRING. KAPTON insulation is brittle and
can shatter, like glass, if stressed like bending over, (180 degrees), and under
VIBRATION from the airplane. Another cardinal rule was broken!!! Maximum
bending of A/C wire is MAXIMUM 90 degrees.

I believe the whole damn air industry must be made aware of how you handle
wire. They should have to pass a FAA CERTIFICATION EXAM. Make some random
interviews of mechanics and maintenance supervisors and see how knowledgable
they are about handling and make wire installations. You might be very
surprised and yet wire is so crucial to flying SAFE, that all personnel
should know how to safely handle wire.

http://www.herald.ns.ca/swissair/Swissair.htmldegy

Recent Repairs, Wire Arcing Eyed in 767 ETOPS Diversion

James T. McKenna/Washington

British investigators are assessing whether recent maintenance and the use of
polyimide-insulated wiring contributed to an inflight electrical fire on a
United Airlines ETOPS 767.

The U.K.'s Air Accidents Investigation Branch (AAIB) is running the
investigation into the Jan. 9 incident, which led to the diversion of the
Zurich-Washington flight to London. The U.S. National Transportation Safety
Board is participating.

The problems on United Flight 965 began shortly after takeoff from Zurich for
a transatlantic flight to Washington's Dulles International Airport, when a
series of apparently unrelated electrical problems began occurring, the
flight crew told investigators.

When the aircraft was west-northwest of Paris, the flight crew was
approaching the point at which they had to decide whether to continue the extended-range, twin-engine overwater operations (ETOPS) flight over the Atlantic. ETOPS rules permit twin-engine aircraft to operate on routes 180
min. or more from the nearest emergency landing airport only if the
aircraft's systems meet strict conditions. Given the electrical problems, the crew opted
to abort the flight and divert to London's Heathrow International Airport.

After an uneventful landing at Heathrow, flight attendants reported smoke in
the first-class cabin and galley. The captain ordered an evacuation after he
brought the 767 to a stop on a taxiway. There were a handful of minor
injuries during the evacuation.

AAIB investigators examining the aircraft found about 10 circuit breakers
open in the cockpit. It is not clear whether the breakers opened in flight or on
the ground.

They also found a roughly 7-in.-long section in a bundle of more than 100
wires that was severely burned and melted. The bundle was in the electrical
and electronics (E&E) bay of the 767-322ER, directly below the first-class
galley.

About three dozen wires in the bundle were damaged by heat or fire. The
twisted strands in one wire were fused into a single strand of copper,
indicating its exposure to sustained high temperatures. There were copper
globules in the damaged area, indicating active arcing occurred there.

All of the damage to the bundle occurred on the inside bend of the bundle's
curve over the top and down the side of a refrigeration unit. There is no
evidence that the fire or heat extended up around the circumference of the
bundle to the top of the bundle.

The exterior of wires on another bundle about an inch away suffered thermal
damage, as did foam on the rear wall of the refrigeration unit.

The unit, an 86-lb. chiller for the first-class galley, had recently
undergone maintenance. Investigators are trying to determine whether mechanics may have nicked insulation on a wire in the damaged bundle in the process of
maneuvering the chiller out of or into its perch in the E&E bay.

Most of the wires in the damaged bundle used ETFE insulation, but all of the
individual damaged wires used Kapton, a type of polyimide-film insulation.
Polyimide insulation has been known to break down under ``arc tracking''
if it has been previously damaged or mishandled.

In arc tracking, a short circuit arcs the polyimide insulated wire and
another conductor. This chars the insulator, making it conductive and capable of
sustaining the arc. Sustained arcs have been shown to propagate along the
wire through continuous insulation charring, triggering arcing in other polyimide-
insulated wires in a bundle.

Photograph: After the United Airlines 767 flight crew diverted to Heathrow,
investigators found concentrated fire and heat damage in one wire bundle in
the aircraft's electronics compartment. Bill Hough photo. -AW&ST 2/9/98