AVIA-1038 Week 1 Day 1 PDF - Fanshawe

Summary

This document provides learning objectives and details for various types of tubing used in aircraft, including copper, aluminum, steel, and titanium. It covers material identification, sizes, fabrication (cutting, bending, flaring), and flareless fittings. It is course material from Fanshawe.

Full Transcript

Learning Objectives Week 1 Day 1

Tubing
Materials & Identification

Fabrication

Cutting, Bending, Flaring

Flareless Fittings
Beading
Fluid Line Identification

1
AVIA-1038D1

2
 General 9-2

Copper
 In the early days of aviation, copper tubing was used
extensively in aviation fluid applications.
 In modern aircraft, aluminum alloy, corrosion resistant
steel or titanium tubing have generally replaced copper
tubing.

3
 General 9-2

Aluminum Alloy Tubing
 Tubing made from 1100 H14 (1/2-hard) or 3003 H14 (1/2-
hard) is used for general purpose lines of low or
negligible fluid pressures, such as instrument lines and
ventilating conduits.
 Tubing made from 2024-T3, 5052-O, and 6061-T6
aluminum alloy materials is used in general purpose
systems of low and medium pressures, such as
hydraulic and pneumatic 1,000 to 1,500 psi systems, and
fuel and oil lines.

4
 General 9-2

Steel
 Corrosion resistant steel tubing, either annealed CRES
304, CRES 321 or CRES 304-1/8-hard, is used extensively
in high pressure hydraulic systems (3,000 psi or more)
for the operation of landing gear, flaps, brakes, and in
fire zones.
 Its higher tensile strength permits the use of tubing
with thinner walls; consequently, the final installation
weight is not much greater than that of the thicker wall
aluminum alloy tubing.

5
 General 9-2

Steel
 Steel lines are used where there is a risk of foreign
object damage (FOD); i.e., the landing gear and wheel
well areas.
 Although identification markings for steel tubing differ,
each usually includes the manufacturer’s name or
trademark, the Society of Automotive Engineers (SAE)
number, and the physical condition of the metal.

6
 General 9-2

Titanium 3AL-2.5V
 This type of tubing and fitting is used extensively in
transport category and high-performance aircraft
hydraulic systems for pressures above 1,500 psi.
 Titanium is 30 percent stronger than steel and 50
percent lighter than steel.
 Cryofit fittings or swaged fittings are used with
titanium tubing.

7
 General 9-2

Titanium 3AL-2.5V
 Do not use titanium tubing and fittings in any oxygen
system assembly.
 Titanium and titanium alloys are oxygen reactive.
 If a freshly formed titanium surface is exposed in
gaseous oxygen, spontaneous combustion could occur
at low pressures.

8
 General 9-2

Material Identification
 Before making repairs to any aircraft tubing, it is
important to make accurate identification of tubing
materials.
 Aluminum alloy, steel, or titanium tubing can be
identified readily by sight where it is used as the basic
tubing material.
 However, it is difficult to determine whether a material
is carbon steel or stainless steel, or whether it is 1100,
3003, 5052-O, 6061-T6 or 2024-T3 aluminum alloy.

9
 General 9-2

Material Identification
 To positively identify the material used in the original
installation, compare code markings of the replacement
tubing with the original markings on the tubing being
replaced.
 On large aluminum alloy tubing, the alloy designation
is stamped on the surface.
 On small aluminum tubing, the designation may be
stamped on the surface; but more often it is shown by a
color code, not more than 4" in width, painted at the
two ends and approximately midway between the ends
of some tubing.
10
 General 9-2

Material Identification
 When the band consists of two colors, one-half the
width is used for each color. [Figure 9-11].

 If the code markings are hard or impossible to read, it
may be necessary to test samples of the material for
hardness-by-hardness testing.

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 General 9-2

Material Identification
 Figure 9-1

12
 General 9-2

Sizes
 Metal tubing is sized by outside diameter (o.d.), which
is measured fractionally in sixteenths of an inch.
 Thus, number 6 tubing is 6/16" (or 3⁄8") and number 8
tubing is 8/16" (or 1⁄2"), and so forth.
 The tube diameter is typically printed on all rigid
tubing.
 In addition to other classifications or means of
identification, tubing is manufactured in various wall
thicknesses.

13
 General 9-2

Sizes
 Thus, it is important when installing tubing to know
not only the material and outside diameter, but also the
thickness of the wall.
 The wall thickness is typically printed on the tubing in
thousands of an inch.
 To determine the inside diameter (i.d.) of the tube,
subtract twice the wall thickness from the outside
diameter.
 For example, a number 10 piece of tubing with a wall
thickness of 0.063" has an inside diameter of 0.625" –
2(0.063") = 0.499".
14
AVIA-1038D1

15
 General 9-2

Fabrication of Metal Tube Lines
 Damaged tubing and fluid lines should be repaired
with new parts whenever possible.
 Unfortunately, sometimes replacement is impractical,
and repair is necessary.
 Scratches, abrasions, or minor corrosion on the outside
of fluid lines may be considered negligible and can be
smoothed out with a burnishing tool or aluminum
wool.

16
 General 9-3

Fabrication of Metal Tube Lines
 Limitations on the amount of damage that can be
repaired in this manner are discussed in this chapter
under “Rigid Tubing Inspection and Repair.” If a fluid
line assembly is to be replaced, the fittings can often be
salvaged; then the repair will involve only tube forming
and replacement.
 Tube forming consists of four processes: Cutting,
bending, flaring, and beading.

17
 General 9-3

Fabrication of Metal Tube Lines
 If the tubing is small and made of soft material, the
assembly can be formed by hand bending during
installation.
 If the tube is 1⁄4" diameter or larger, hand bending
without the aid of tools is impractical.

18
 General 9-3

Tube Cutting
 When cutting tubing, it is important to produce a
square end, free of burrs.
 Tubing may be cut with a tube cutter or a hacksaw.
 The cutter can be used with any soft metal tubing, such
as copper, aluminum, or aluminum alloy.
 Correct use of the tube cutter is shown in Figure 9-2.
 Special chipless cutters are available for cutting
aluminum 6061-T6, corrosion resistant steel and
titanium tubing.

19
 General 9-3

Tube Cutting
 Figure 9-2

20
 General 9-3

Tube Cutting
 A new piece of tubing should be cut approximately 10
percent longer than the tube to be replaced to provide
for minor variations in bending.
 Place the tubing in the cutting tool, with the cutting
wheel at the point where the cut is to be made.
 Rotate the cutter around the tubing, applying a light
pressure to the cutting wheel by intermittently twisting
the thumbscrew.

21
 General 9-3

Tube Cutting
 Too much pressure on the cutting wheel at one time
could deform the tubing or cause excessive burring.
 After cutting the tubing, carefully remove any burrs
from inside and outside the tube.
 Use a knife or the burring edge attached to the tube
cutter.
 The deburring operation can be accomplished by the
use of a deburring tool as shown in Figure 9-3.

22
 General 9-3

Tube Cutting
 Figure 9-3

23
 General 9-3

Tube Cutting
 This tool is capable of removing both the inside and
outside burrs by just turning the tool end for end.
 When performing the deburring operation, use extreme
care that the wall thickness of the end of the tubing is
not reduced or fractured.
 Very slight damage of this type can lead to fractured
flares or defective flares which will not seal properly.
 Use a fine-tooth file to file the end square and smooth.

24
 General 9-2

Tube Cutting
 If a tube cutter is not available, or if tubing of hard
material is to be cut, use a fine-tooth hacksaw,
preferably one having 32 teeth per inch.
 The use of a saw will decrease the amount of work
hardening of the tubing during the cutting operation.
 After sawing, file the end of the tube square and
smooth, removing all burrs.
 An easy way to hold small diameter tubing, when
cutting it, is to place the tube in a combination flaring
tool and clamp the tool in a vise.

25
 General 9-3

Tube Cutting
 Make the cut about one half inch from the flaring tool.
 This procedure keeps sawing vibrations to a minimum
and prevents damage to the tubing if it is accidentally
hit with the hacksaw frame or file handle while cutting.
 Be sure all filings and cuttings are removed from the
tube.

26
 General 9-3

Tube Bending
 The objective in tube bending is to obtain a smooth
bend without flattening the tube.
 Tubing under 1⁄4" in diameter usually can be bent
without the use of a bending tool.
 For larger sizes, either portable hand benders or
production benders are usually used.
 Table 9-4 shows preferred methods and standard bend
radii for bending tubing by tube size.

27
 General 9-4

Tube Bending
 Table 9-4

28
 General 9-3

Tube Bending
 Using a hand bender, insert the tubing into the
groove of the bender, so that the measured end is left of
the form block.
 Align the two zeros and align the mark on the tubing
with the L on the form handle.
 If the measured end is on the right side, then align the
mark on the tubing with the R on the form handle.
 With a steady motion, pull the form handle till the zero
mark on the form handle lines up with the desired angle
of bend, as indicated on the radius block. [Figure 9-5]

29
 General 9-4

Tube Bending
 Bend the tubing carefully to avoid excessive flattening,
kinking, or wrinkling.
 A small amount of flattening in bends is acceptable, but
the small diameter of the flattened portion must not be
less than 75 percent of the original outside diameter.
 Tubing with flattened, wrinkled, or irregular bends
should not be installed.
 Wrinkled bends usually result from trying to bend thin
wall tubing without using a tube bender.

30
 General 9-4

Tube Bending
 Figure 9-5

31
 General 9-4

Tube Bending
 Excessive flattening will cause fatigue failure of the
tube.
 Examples of correct and incorrect tubing bends are
shown in Figure 9-8.
 Tube bending machines for all types of tubing are
generally used in repair stations and large maintenance
shops.
 With such equipment, proper bends can be made on
large diameter tubing and on tubing made from hard
material.

32
 General 9-5

Tube Bending
 Figure 9-8

33
 General 9-4

Tube Bending
 The production CNC™ tube bender is an example of
this type of machine. [Figure 9-9]
 The ordinary production tube bender will
accommodate tubing ranging from 1⁄4" to 1 1⁄2" outside
diameter.
 Benders for larger sizes are available, and the principle
of their operation is similar to that of the hand tube
bender.
 The radius blocks are so constructed that the radius of
bend will vary with the tube diameter.
 The radius of bend is usually stamped on the block.
34
 General 9-5

Tube Bending
 Figure 9-9

35
 General 9-5

Alternative Bending Methods
 When hand or production tube benders are not
available or are not suitable for a particular bending
operation, a filler of metallic composition or of dry sand
may be used to facilitate bending.
 When using this method, cut the tube slightly longer
than is required.
 The extra length is for inserting a plug (which may be
wooden) in each end.
 The tube can also be closed by flattening the ends or by
soldering metal disks in them.

36
 General 9-5

Alternative Bending Methods
 After plugging one end, fill and pack the tube with fine,
dry sand and plug tightly.
 Both plugs must be tight so they will not be forced out
when the bend is made.
 After the ends are closed, bend the tubing over a
forming block shaped to the specified radius.
 In a modified version of the filler method, a fusible alloy
is used instead of sand.
 In this method, the tube is filled under hot water with a
fusible alloy that melts at 160°F.

37
 General 9-5

Alternative Bending Methods
 The alloy-filled tubing is then removed from the water,
allowed to cool, and bent slowly by hand around a
forming block or with a tube bender.
 After the bend is made, the alloy is again melted under
hot water and removed from the tubing.
 When using either filler methods, make certain that all
particles of the filler are removed.
 Visually inspect with a borescope to make certain that
no particles will be carried into the system in which the
tubing is installed.

38
 General 9-5

Alternative Bending Methods
 Store the fusible alloy filler where it will be free from
dust or dirt.
 It can be remelted and reused as often as desired.
 Never heat this filler in any other way than the
prescribed method, as the alloy will stick to the inside
of the tubing, making them both unusable.

39
 General 9-5

Tube Flaring
 Two kinds of flares are generally used in aircraft tubing:
the single flare and the double flare.
 [Figure 9-10A and B] Flares are frequently subjected to
extremely high pressures; therefore, the flare on the
tubing must be properly shaped or the connection will
leak or fail.
 A flare made too small produces a weak joint, which
may leak or pull apart; if made too large, it interferes
with the proper engagement of the screw thread on the
fitting and will cause leakage.

40
 General 9-5

Tube Flaring
 Figure 9-10

41
 General 9-5

Tube Flaring
 Figure 9-10

42
 General 9-5

Tube Flaring
 A crooked flare is the result of the tubing not being cut
squarely.
 If a flare is not made properly, flaws cannot be
corrected by applying additional torque when
tightening the fitting.
 The flare and tubing must be free from cracks, dents,
nicks, scratches, or any other defects.
 The flaring tool used for aircraft tubing has male and
female dies ground to produce a flare of 35° to 37°.

43
 General 9-5

Tube Flaring
 Under no circumstance is it permissible to use an
automotive-type flaring tool which produces a flare of
45°. [Figure 9-11].
 The single-flare hand flaring tool, similar to that shown
in Figure 9-12, is used for flaring tubing.
 The tool consists of a flaring block or grip die, a yoke,
and a flaring pin.
 The flaring block is a hinged double bar with holes
corresponding to various sizes of tubing.

44
 General 9-6

Tube Flaring
 Figure 9-11

45
 General 9-6

Tube Flaring
 Figure 9-12

46
 General 9-5

Tube Flaring
 These holes are countersunk on one end to form the
outside support against which the flare is formed.
 The yoke is used to center the flaring pin over the end
of the tube to be flared.
 Two types of flaring tools are used to make flares on
tubing: the impact type and the rolling type.

47
 General 9-6

Instructions for Rolling-Type Flaring Tools
 Use these tools only to flare soft copper, aluminum, and
brass tubing.
 Do not use with corrosion resistant steel or titanium.
 Cut the tube squarely and remove all burrs.
 Slip the fitting nut and sleeve on the tube.
 Loosen clamping screw used for locking the sliding
segment in the die holder.
 This will permit their separation.

48
 General 9-6

Instructions for Rolling-Type Flaring Tools
 The tools are self-gauging; the proper size flare is
produced when tubing is clamped flush with the top of
the die block.
 Insert tubing between the segments of the die block
that correspond to the size of the tubing to be flared.
 Advance the clamp screw against the end segment and
tighten firmly.
 Move the yoke down over the top of the die holder and
twist it clockwise to lock it into position.

49
 General 9-6

Instructions for Rolling-Type Flaring Tools
 Turn the feed screw down firmly and continue until a
slight resistance is felt.
 This indicates an accurate flare has been completed.
 Always read the tool manufacturer’s instructions,
because there are several different types of rolling-type
flaring tools that use slightly different procedures.

50
 General 9-6

Double Flaring
 A double flare is used on soft aluminum alloy tubing
3⁄8" outside diameter and under.
 This is necessary to prevent cutting off the flare and
failure of the tube assembly under operating pressures.
 A double flare is smoother and more concentric than a
single flare and therefore seals better.
 It is also more resistant to the shearing effect of torque.

51
 General 9-7

Double Flaring Instructions
 Deburr both the inside and outside of the tubing to be
flared.
 Cut off the end of the tubing, if it appears damaged.
 Anneal brass, copper, and aluminum by heating to a
dull red and cool rapidly in cold water.
 Open the flaring tool by unscrewing both clamping
screws.
 Select the hole in the flaring bar that matches the
tubing diameter and place the tubing with the end you
have just prepared, extending above the top of the bar
by a distance equal to the thickness of the shoulder of
the adapter insert. 52
 General 9-7

Double Flaring Instructions
 Tighten clamping screws to hold tubing securely.
 Insert pilot of correctly sized adapter into tubing.
 Slip yoke over the flaring bars and center over adapter.
 Advance the cone downward until the shoulder of the
adapter rests on the flaring bar.
 This bells out the end of the tubing.
 Next, back off the cone just enough to remove the
adapter.
 After removing the adapter, advance the cone directly
into the belled end of the tubing.
53
 General 9-7

Double Flaring Instructions
 This folds the tubing on itself and forms an accurate
double flare without cracking or splitting the tubing.
 To prevent thinning out of the flare wall, do not
overtighten. [Figure 9-13].

 How To Make a Double Flare

54
 General 9-7

Double Flaring Instructions
 Figure 9-13

55
 General 9-7

Fittings
 Rigid tubing may be joined to either an end item (such
as a brake cylinder), another section of either rigid
tubing, or to a flexible hose (such as a drain line).
 In the case of connection to an end item or another
tube, fittings are required, which may or may not
necessitate flaring of the tube.
 In the case of attachment to a hose, it may be necessary
to bead the rigid tube so that a clamp can be used to
hold the hose onto the tube.

56
 General 9-7

Flareless Fittings
 Although the use of flareless tube fittings eliminates all
tube flaring, another operation referred to as presetting
is necessary prior to installation of a new flareless tube
assembly.
 Flareless tube assemblies should be preset with the
proper size presetting tool or operation.
 The presetting operation is performed as follows:
Cut the tube to the correct length, with the ends
perfectly square.
 Debur the inside and outside of the tube.

57
 General 9-7

Flareless Fittings
 Slip the nut, then the sleeve, over the tube, lubricate the
threads of the fitting and nut with hydraulic fluid.
 Place the fitting in a vise and hold the tubing firmly and
squarely on the seat in the fitting. (The tube must
bottom firmly in the fitting.)
 Tighten the nut until the cutting edge of the sleeve
grips the tube.
 To determine this point, slowly turn the tube back and
forth while tightening the nut.
 When the tube no longer turns, the nut is ready for
tightening.
58
 General 9-7

Flareless Fittings
 Final tightening depends upon the tubing.
 For aluminum alloy tubing up to and including ½"
outside diameter, tighten the nut from 1 to 1 1/6 turns.
 For steel tubing and aluminum alloy tubing over ½ "
outside diameter, tighten 1 1/6 to 1 ½ turns.

 After presetting the sleeve, disconnect the tubing from
the fitting and check the following points:
 [Figure 9-14]The tube should extend 3/32" to 1/8"
beyond the sleeve pilot; otherwise, blowoff may occur.

59
 General 9-7

Flareless Fittings
 The sleeve pilot should contact the tube or have a
maximum clearance of.005" for aluminum alloy tubing
or.015" for steel tubing.
 A slight collapse of the tube at the sleeve cut is
acceptable.
 No movement of the sleeve pilot, except rotation, is
permissible.

 How to Assemble Tube Fittings Swagelok

60
 General 9-8

Flareless Fittings
Figure 9-14

61
 General 9-7

Beading
 Beading enlarges an area of a tube’s circumference to
provide a section where pressure can be applied with a
clamp.
 Tubing may be beaded with a hand beading tool,
machine beading rolls, or with grip dies.
 The method used depends on the diameter and wall
thickness of the tube and the material of which it was
made.
 The hand beading tool is used with tubing having 1⁄4"
to 1" outside diameter. [Figure 9-15]

62
 General 9-7

Beading
 The bead is formed by using the beader frame with the
proper rollers attached.
 The inside and outside of the tube is lubricated with
light oil to reduce the friction between the rollers
during beading.
 The sizes, marked in sixteenths of an inch on the
rollers, are for the outside diameter of the tubing that
can be beaded with the rollers.
 Separate rollers are required for the inside of each
tubing size, and care must be taken to use the correct
parts when beading.
63
 General 9-9

Beading.
 Figure 9-15

64
 General 9-8

Beading
 The hand beading tool works somewhat like the tube
cutter in that the roller is screwed down intermittently
while rotating the beading tool around the tubing.
 In addition, a small vise (tube holder) is furnished with
the kit.
 Other methods and types of beading tools and
machines are available, but the hand beading tool is
used most often.

65
 General 9-8

Beading
 As a rule, beading machines are limited to use with
large diameter tubing, over 1 15⁄16", unless special rollers
are supplied.
 The grip-die method of beading is confined to small
tubing.

 Beading Aluminum Line

66
 General 9-8

Fluid Line Identification
 Fluid lines in aircraft are often identified by markers
made up of color codes, words, and geometric symbols.
 These markers identify each line’s function, content,
and primary hazard.
 Figure 9-16 illustrates the various color codes and
symbols used to designate the type of system and its
contents.
 Fluid lines are marked, in most instances with 1" tape or
decals. [Figure 9-17A]

67
 General 9-8

Fluid Line Identification
 On lines 4" in diameter (or larger), lines in oily
environment, hot lines, and on some cold lines, steel
tags may be used in place of tape or decals, as shown in
Figure 9-17B.
 Paint is used on lines in engine compartments, where
there is the possibility of tapes, decals, or tags being
drawn into the engine induction system.
 In addition to the above-mentioned markings, certain
lines may be further identified regarding specific
function within a system; for example, drain, vent,
pressure, or return.
68
 General 9-10

Fluid Line Identification
 Figure 9-16

69
Fluid Line Identification

70
 General 9-10

Fluid Line Identification
 Figure 9-17

Tube content Hazard

71
 General 9-10

Fluid Line Identification
 Figure 9-17

72
 General 9-8

Fluid Line Identification
 Lines conveying fuel may be marked FLAM. [Figure
9-17]
 Lines containing toxic materials are marked TOXIC
in place of FLAM.
 Lines containing physically dangerous materials,
such as oxygen, nitrogen, or Freon™, may be marked
PHDAN. (physically dangerous)
 Aircraft and engine manufacturers are responsible
for the original installation of identification
markers, but the aviation mechanic is responsible
for their replacement when it becomes necessary.
73
 General 9-8

Fluid Line Identification
 Tapes and decals are generally placed on both ends of a
line and at least once in each compartment through
which the line runs.
 In addition, identification markers are placed
immediately adjacent to each valve, regulator, filter, or
other accessory within a line.
 Where paint or tags are used, location requirements are
the same as for tapes and decals.

74