مشروع مجموعة
رشاد أمان عثمان
احنا اتكلمنا عن اللحام للالمونيوم بوجه الخصوص عن
Soldering and brazing of Aluminum
وحاولنا ان نستعرض المعلومات الكافية عنهم
من خلال طريقة اللحام والمشاكل التي تواجه هذه الطريقة
واهم التطبيقات
اتمني الاستفادة
4. Soldering Aluminum
• What is soldering ?
• Soldering is by definition a low temperature joining process. Therefore,
less distortion of the aluminum component is expected by soldering than
by brazing, welding or other fusion joining processes.
5. 5
Soldering
• Solder is divided into two
categories;
– Soft
– Hard
Relies upon capillary action.
Describe soft soldering?
How is hard soldering different from soft soldering?
What is capillary action?
What are the requirements for capillary action?
6. Soldering Process
1. The joint area is cleaned and fluxed.
2. A heat source is used to raise the
temperature of the base metal above the
melting of the filler metal (<840 oF).
3. The filler metal is added to the joint.
Filler material should melt from the
heat of the metal, not the heat source.
4. The filler metal flows into the joint and
adheres to the surfaces.
5. The heat source is removed and the filler
metal solidifies, bonding the surfaces
together.
7. • Typical applications of aluminum soldering:
• heat exchanger assembly, electronic/electrical capacitor
manufacturing, and light bulb manufacturing.
• None of these applications requires high tensile strength, but,
they do require the solder to not cause galvanic
• corrosion over time.
8. Appropriate solders for Aluminum
• -Soldering requires proper heat on the component, not on
the solder. Because of the highthermal conductivity and
reflectivity of aluminum, it has been found that neither
oxy-acetyleneflame torch, plasma arc, laser, induction
heater, nor thermal spray is capable of providing
goodresults.
• -high density infrared source of 300kWplasma lamp has
been demonstrated to have successful results with 80 wt%
Zn- 20 wt%Al andflux at a soldering temperature of 490°C.
• Mechanical tests showed that the joint area is strongerthan
the parent material with minimum softening.
9. Temperatures and stresses
• Soldering temperatures of 225°C to 490°C are well below the 661°C
aluminummelting temperature although 490°C is above most annealing
temperatures.
• -Stresses in the aluminum from shearing, drawing, and heat-treating are changed
by the localized heatingencountered during soldering and distortion may result.
• HEATING METHODS:-
• -open flame cannot be considered
• -Plasma Arc wire feed equipment on aluminumPanels :it was observed that the
heat is solocalized that neither soft, nor hard solders could flow consistently well
between both panels.
• -Preheatingbetter capillary flowbetween the panels, hot cracking became evident
in some samples due to the rapid buildup ofheat from the plasma arc.
• -Induction provides a rapid, delocalized heating technique for even large parts.
Unfortunately,induction heating did not provide sufficient heat to melt the solder
• Both tin-based and zinc-based alloys have also been tried using the thermal spray
to deposit on aluminum body panels as well as galvanized steel. This process
does not enable solders tocapillary or flow between panels.
10. Simplified steps for soldering aluminum:
Steps
• 1-For some difficult to solder and large surface area
joints, it may be extremely helpful to pre-tin the joint
area on each part with the solder before setting up to
join the parts. Simply follow the steps below to coat
the joint area of each part with an even coat of solder.
Then, after the parts have cooled, follow the steps
again to join the parts. The 1-2-3 rule applies here as
well. Do not pre-tin one day and solder the next. A
fresh oxide-free surface is important to soldering
success. Pre-tinning your parts with the right solder
can greatly improve joints on difficult to solder metals
and large surface area parts.
11.
12. • 2-Pre-clean the parent metal or metals to be joined. Prepare aluminum
surfaces with a stainless steel wire brush. Breaking the tough aluminum
oxide coating on the aluminum parts is the secret to aluminum soldering.
These barriers reform quickly, so agitate, flux and solder in a rapid
sequence.
13. • 3-Apply the appropriate aluminum soldering flux to break
the oxide barrier and draw the solder into the joint/repair
area. You may easily use the solder rod to spread the flux
14. • 4-Use a soft flame, heat gun or soldering iron to heat the parent metal adjacent
to the repair area. A direct flame on the repair area is likely to overheat the solder
and flux. If using a torch, hold the torch tip 4 to 6 inches away from the parent
metal. If it is necessary to apply the flame directly to the rod or flux, pull the torch
tip back even farther from the work surface and keep it moving.
15. • 5-The flux will begin to bubble and turn light brown. Besides preparing
the parent metal for the solder, these changes indicate the proper working
temperature for the flux. If the flux turns black, let the area cool, clean it &
start over.
16. • 6-When the flux bubbles and turns brown, it is time to apply the rod.
Drag the rod over the area to be soldered, until it begins to flow. Once the
solder starts to flow remove the heat. If additional layers are needed,
continue to drag the rod over the area. With some applications, for
example with very thin wires, it may be helpful to tin the aluminum
surface with the rod before soldering the parts together. In this case,
follow steps 1 through 5 to apply an even coat of solder to the aluminum
parts. Let these parts cool, and then follow steps 1 through 5 again,
soldering the parts together. This will often result in a more consistent
solder joint for small parts.
17. • 7-Observe the solder deposit. The solder
should bond smoothly
18. • 8-Remove the excess flux with warm water and a wire brush. Flux residue is
acidic and should ALWAYS be removed, even for “No Clean” fluxes.
Notes :
• -The quality of the interface increased with increasing temperatures
• -Do not overheat. The rod will melt if overheated, but will not bond properly. (Really cannot
emphasize this enough. Soldering is a low heat process designed so that the electronic parts
and base metals are not damaged during joining.)
19.
20. Aluminum Brazing
Introduction
Soldering and Brazing are joining processes where
materials, similar or dissimilar, are bonded
together using a heating method and a filler
metal without melting the base materials. The
filler metal melts, wets(flowing of filler metal) the
base materials, and subsequently flows by
capillary action. Wetting of the base materials by
the filler metals is enabled by the use of a
suitable flux or by acoustic vibrations.
21.
22. Aluminum Brazing
• Heavy metal brazing alloys cannot be used for brazing
aluminum due to the melting point of aluminum and its alloys
and due to the required corrosion resistance of the brazed
joint. As a result, brazing alloys based on aluminum,
containing no or very small quantities of heavy metals and at
least 70% aluminum, are employed. Most commercial filler
metals are based on AL-SI system with silicon contents in the
range 7-12% . In addition to a suitable brazing alloy, for
brazing one also requires a medium which removes the
surface oxide from the base material and keeps this surface
bare during the brazing procedure. As well as fluxes, a vacuum
is also considered a medium .The non-heat treatable alloys
that have been brazed most succefully are the 1xxx and 3xxx
and the low-magnesium members of 5xxx . of the heat
treatable alloys only the 6xxx.
23.
24. How to braze Aluminum?
• Knowing how to braze aluminum can be a
useful skill for anyone who is faced with a
variety of at-home repairs. Brazing aluminum
is a quick and inexpensive option for repairing
leaks, cracks, or holes in aluminum and is
often found in air-conditioning repairs. When
compared to welding equipment, aluminum
brazing equipment is inexpensive, portable,
and does not require high amounts of voltage.
26. 2-Clean all dirt, oil, paint, or other residue from the area to be repaired by
aluminum brazing. Use a degreasing solvent to get rid of oil and grease.
Depending on the size of the repaired area, you may need to sandblast the
area or use an emery cloth, grinding wheel, or file.
28. 4-Use a brush to apply the flux appropriate to the temperatures and the
metal. An all-purpose flux covers a wide range of temperatures and is beneficial
to have on hand for general purpose brazing. Add flux by dipping the filler rod
into the flux. You may also use flux-coated rods to eliminate this step. The flux-
coated rods apply the flux during the aluminum brazing process.
29. 5-Heat the repaired area with a propane or acetylene torch until the
aluminum shows an orange bloom. This happens when the metal gets very
hot. Once you apply a flux, it should change colors or turn clear throughout.
30. 6-Apply the filler metal by running a brazing rod along the crack or the
joint. The heat of the metal will melt the filler into the area needing the
repair. Move the flame of the torch on and off as needed to melt the rod.
31. 7-Remove the flux after the filler material has solidified by dipping the part
or pouring hot water on the repair. The flux will flake off. If it does not come
off, use a wire brush to gently scrub the brazed area while wet or still in the
hot water.
32. 8-Polish the area with an emery cloth after the metal
has cooled completely.
33. 9-Coat the area with a rust-resistant coating if you are
not immediately finished with the area.
34. Methods of removing the oxide layer
Vacuum brazing
• The coefficient of expansion of aluminum is about three times as great as
that of aluminum oxide. That’s why the oxide layers crack up on heating
and the liquid brazing alloy can pass through these cracks down to the
bare base material. The aluminum oxide layer becomes mechanically
detached. Oxidation of the aluminum in the cracks during the heating
phase can only be prevented if the atmosphere is completely devoid of
oxygen.
• Using fluxes :-
• flux is required to prevent oxides from forming while the metal is heated.
The flux also serves the purpose of cleaning any contamination left on the
brazing surfaces. Flux can be applied in any number of forms including flux
paste, liquid, powder or pre-made brazing pastes that combine flux with
filler metal powder.
35. Brazing techniques
• Flame brazing
• In flame brazing, the components are heated to brazing temperature with
the burner Natural gas, sewer gas, propane and acetylene are used as fuel
gases. The fuel gases are combined with drawn-in air compressed air and
occasionally also with oxygen .In manual burner brazing, the area of the
component to be brazed is applied with flux. For brazing bulk quantities of
items ,burner-heated brazing machines have been increasingly used in
recent years.
36. • Induction brazing
• Induction brazing of aluminum is virtually only used
for brazing compensating bases. The brazing of
compensating bases involves connecting an
aluminum plate to a chromium-nickel steel cooking
pot.
37. • Open furnace brazing:-
• The brazing joints are wetted with flux and then the
component is passed through the furnace. As the
brazing is carried out in air, a corrosive flux must be
used for this brazing process.
38. • Furnace brazing under controlled atmospheres:-
• reduction of the aluminum oxide layer is not possible at
brazing temperature even in pure hydrogen. It is hence
necessary to use fluxes, even in inert gas atmospheres.
However, only the non-corrosive type are employed. The most
commonly used inert gas is nitrogen although
nitrogen/hydrogen mixtures are also used.
39. Brazing Joints
• The tensile strength of brazing filler material
is less than steel.
• The strength of the weld is increased if the
joints are modified to increase the surface
area.
Tensile strength of
brazing rod is ~40,000
psi.
Tensile strength of
steel electrode is
36,000 to 50,000 psi.
40. Reference
1. Brazing aluminum
W. Kohlweiler , Braze Tec GmbH, Hanau
2.the Copper Development Association.
3. The Harris Products Group
www.harrisproductsgroup.com