Soldering, Brazing and Braze Welding

1. Soldering, Brazing and Braze Welding Ag Metals I Welding Principles & Applications Chapter 31

2. Objectives • Define the terms soldering, brazing and braze welding • Explain the advantages and disadvantages of liquid-solid phase bonding • Describe the functions of fluxes in making proper liquid-solid phase bonded joints

3. Introduction • Soldering and brazing are classified by the AWS as liquid-solid phase bonding processes • This means… • The filler metals is melted • The base material or materials is not melted • The phase is the temperature at which bonding takes place between the filler and base • The bond between the base material and filler material is metallurgical because no alloying or melting of the base metal occurs • If done correctly, this bond results in a joint that has 5 X’s the tensile strength of that of the filler metal

4. Soldering & Brazing • Soldering • Takes place at a temperature below 804˚ F • Brazing • Takes place at a temperature above 804˚ F • This is the only difference between the two

5. Brazing Brazing Braze Welding Does not need capillary action to pull filler metal into the joint • Parts being joined must be fitted so the joint spacing is very small • This small spacing allows capillary action to draw the filler metal into the joint when the parts reach the proper phase temperature

6. Advantages of Soldering and Brazing • Low temperature • Permanent or Temporary Joining • Dissimilar materials can be joined • Speed • Less chance of damage • Slow rate of heating/cooling • Parts of varying thickness can be joined • Easy realignment

7. Tensile Strength • The joints ability to withstand being pulled apart • Brazed joints can be made to have a tensile strength of 4-5 X’s higher than the filler metal itself • As joint spacing decrease, surface tension increases the tensile strength of the joint

8. Shear Strength • A joints ability to withstand a parallel force • Depends upon the amount of overlapping area of the base parts • The great the area of overlap, the greater the strength

9. Ductility • The joints ability to bend without failing • Most soldering and brazing alloys are ductile metals making the joints they are made with ductile as well

10. Fatigue Resistance • The joints ability to be bent repeatedly without exceeding its elastic limit and without failure • Fairly low for most soldered or brazed joints • Fatigue failures may also occur as a result of vibration

11. Corrosion Resistance • The joints ability to resist chemical attack • Compatibility of base metals to filler metals will determine corrosion resistance

12. Functions of Flux • Remove any oxides that form as a result of heating the parts • Promote wetting • Aid in capillary action

13. Flux in General • When heated to its reacting temperature must be thin and flow through the gap provided at the joint • As it flows through the joint it absorbs and dissolves oxides, allowing the molten filler metal to be pulled in behind it. • Once the joint is complete the flux material should be completely removable

14. Types of Fluxes • Solids • Powders • Paste • Liquids • Sheets • Rings • Washers • They are also available mixed with filler metal, inside the filler metal or on the outside of filler metal

15. Fluxing Action • Will remove light surface oxides, promote wetting, and aid in capillary action • But they do not eliminate the need for good joint cleaning • Flux will not remove oil, dirt, paint, glue, heavy oxides or other surface contaminants

16. Soldering & Brazing Fluxes • Soldering Fluxes are chemical compounds such as • Muriatic acid (hydrochloric acid) • Sal ammoniac (ammonium chloride) • Rosin • Brazing Fluxes are chemical compounds such as • Chemical compounds such as • Fluorides • Chlorides • Boric acids • Alkalies

17. What They Do • React to dissolve, absorb or mechanically break up thin surface oxides that are formed as the parts are being heated • Must be stable and remain active through the entire temperature range of the solder or braze filler metal • Chemicals react as either acids or bases • Some dip fluxes are salts

18. General • Methods are grouped according to which heat is applied • Torch • Furnace • Induction • Dip • Resistance

19. Torch Soldering and Brazing • Oxyfuel or air-fuel torches • Acetylene is the most often used but is not as preferable when compared to other fuel gases • This is due to uneven heating

20. Torch Soldering and Brazing Advantages Disadvantages Overheating Skill Fires • Versatility • Portability • Speed

21. Furnace Soldering and Brazing • Parts are heated to their soldering or brazing temperature by passing them through a furnace

22. Furnace Soldering and Brazing Advantages Disadvantages Size Heat damage • Temperature control • Controlled atmosphere • Uniform heating • Mass production

23. Induction Soldering and Brazing • Uses high frequency electrical current to establish a corresponding current on the surface of the part • The current on the part causes rapid and very localized heating of the surface only • Little if any internal heating of the part except by conductivity of heat from the surface

24. Induction Soldering and Brazing Advantages Disadvantages Distortion Lack of temperature control Incomplete penetration • Speed • Very little time is required for the part to reach the desired temperature

25. Dip Soldering and Brazing • Two types • Molten flux bath • Molten metal bath

26. Molten Flux Method • Soldering or brazing filler metal in a suitable form is preplaced in the joint and the assembly is immersed in a bath of molten flux • The bath supplies the heat to preheat the joint and fuse the solder or braze metal and it provides protection from oxidation

27. Molten Metal Method • Prefluxed parts are immersed in a bath of fused solder or braze metal which is protected by a cover of molten flux • Method is confined to wires and other small parts • Once removed from the bath, the ends of the wires or parts must not be allowed to move until the solder or braze metal has solidified

28. Dip Soldering and Brazing Advantages Disadvantages Steam explosions Corrosion Size Quantity • Mass production • Corrosion protection • Distortion minimized

29. Resistance Soldering and Brazing • Electric current is passed through the part • Resistance of the part to the current flow results in the heat needed to produce the bond • Flux is usually preplaced • Material must have sufficient electrical resistance to produce the desired heating • Machine used in this process resembles a spot welder

30. Resistance Soldering Brazing Advantages Disadvantages Distortion Conductors Joint Design • Localized heating • Speed • Multiple spots

31. Special Methods • Ultrasonic method • Uses high-frequency sound waves are used to produce the bond or aid with heat in the bonding • Diffusion • Uses pressure and may use heat or ultrasound to form a bond • Infrared Light • Uses infrared light to heat the part for soldering or brazing

33. General • Soldering and brazing metals are alloys or two or more metals • Each alloy is available in a variety of percentage mixtures • Almost all have a paste range • A paste range is the temperature range in which a metal is partly solid and partly liquid as it is heated or cooled • It is important that joints not be moved during this stage, if they are they may crumble like dry clay and destroy the bond

34. Soldering Alloys • Usually identified by their major alloying elements • The major types of solder alloys are • Tin-lead • Tin-antimony • Cadmium-silver • Cadmium-zinc

35. Tin-lead • Most popular • Least expensive • 61.9% tin and 38.1% lead • Melts at 362˚F • No paste range • Most commonly used on electrical connections • Must never be used for water piping • Also not allowed by most codes for use on water or food handling equipment

36. Tin-antimony • Higher tensile strength & lower creep • Most common is 95/5 or 95% tin, 5% antimony • Most commonly used in plumbing because it is lead free

37. Cadmium-silver • Excellent wetting, flow and strength • Expensive • High temp solders because they retain their strength at temperatures above other solders • Used to join aluminum to itself or other metals • Most often seen used in piping for air conditioning equipment

38. Brazing Alloys • Denoted by the letter B to indicate the alloy is used for brazing • Next series of letters in the classification indicates the atomic symbol of metals used to make the alloy

39. Copper-zinc • Most popular brazing alloy • Available as regular and low-fuming • Zinc in the braze metal has a tendency to burn out if overheated • Overheating is indicated by a red glow on the molten pool which gives off white smoke • The white smoke is zinc oxide, if breathed in it can cause zinc poisoning. Use of low fuming alloy helps eliminate this problem • Examples of low fuming alloys are RCuZn-B and RCuZn-C

40. Copper-zinc & Copper-phosphorus A5.8 • Copper-zinc filler rods are often grouped together and called brazing rod • 5 classifications • Copper-zinc • Navel Brass • Manganese-Bronze • High silicon-Bronze • Nickel-Bronze

41. Copper-phosphorus • Referred to as phos-copper • Good fluidity and wettability • Used in A/C and plumbing to join copper piping

42. Copper-phosphorus-silver • Referred to as sil-phos • Similar to copper-phosphorus except the silver gives the alloy better wetting and flow characteristics • Not necessary to use flux when joining copper pipe • Most common brazing alloy used in A/C compressor fittings

43. Silver-copper • Can be used to join almost any metal, except aluminum, magnesium, zinc and a few other low-melting metals • Often referred to as silver braze • Most versatile • Among most expensive alloys except gold

44. Nickel • Used for joining materials that need high strength and corrosion resistance at elevated temperatures • Applications include • Joining turbine blades in jet engines • Torch parts • Furnace parts • Nuclear reactor tubing • When used on copper based alloys, the nickel may diffuse into copper, stopping its capillary flow

45. Nickel and Nickel Alloys A5.14 • Increase being used as a substitute for silver-based alloy • More difficult to use than silver due to lower wetting and flow characteristics • Higher strength than silver • 7 classes • BNi-1: high strength, heat resistant, used in jet engine parts • BNi-2 • BNi-3: high flow rate, excellent for close fitted joints • BNi-4: higher surface tension than other nickel filler rods, allows larger fillets and poor-fitted joins to be filled • BNi-5: high oxidation resistance and high strength at elevated temps, can be used for nuclear applications • BNi-6: extremely free flowing, good wetting characteristics, high corrosion resistance • BNi-7:high resistance to erosion and can be used for thin or honeycomb structures

46. Aluminum-silicon • Used to join most aluminum sheet and cast alloys • AWS type 1 flux must be used • Must guard against overheating

47. Copper and copper alloys A5.7 • BCu-1 • Used to join ferrous, nickel and copper-nickel • BCu-2 • Similar applications to 1 • Contains organic compounds to tie up porosity

48. Silver & Gold • Used in small quantities when joining metals that are under corrosive conditions and high joining ductility is needed or low electrical resistance is important • Increasing price and decreasing availability

49. Joint Design • Spacing between the parts being joined affects tensile strength • Strongest joints are obtained when the parts are lapped • Butt joint strength can be increased by increasing the area being joined • Joint preparation is also very important • Surfaces must be clean and free of oil, dirt, paint, oxides • Soldering or brazing should begin as soon the parts are cleaned to avoid further contamination

50. Building Up Surfaces and Filling Holes • Braze metal can be used to build up worn parts • Ideal for parts that receive limited abrasive wear because buildup is easily machinable • Has no hard spots to make remachining difficult • Good for both round and flat stock • Low temperature used does not tend to harden the base metal • Holes in light gauge metal can be filled and ground flush leaving a strong patch with minimum distortion