Fluxes for metal joining The composition of fluxes is tailored for the required properties - the base metals and their surface preparation (which determine the composition and thickness of surface oxides), the solder (which determines the wetting properties and the soldering temperature), the corrosion resistance and ease of removal, and others. Fluxes for soft soldering are typically of organic nature, though inorganic fluxes, usually based on halogenides or acids, are also used in non-electronics applications. Fluxes for brazing operate at significantly higher temperatures and are therefore mostly inorganic; the organic compounds tend to be of supplementary nature, e.g. to make the flux sticky at low temperature so it can be easily applied. The surface of the tin-based solder is coated predominantly with tin oxides; even in alloys the surface layer tends to become relatively enriched by tin. Fluxes for indium and zinc based solders have different compositions than fluxes for ordinary tin-lead and tin-based solders, due to different soldering temperatures and different chemistry of the oxides involved. Organic fluxes are unsuitable for flame soldering and flame brazing, as they tend to char and impair solder flow. Some metals are classified as "unsolderable" in air, and have to be either coated with another metal before soldering or special fluxes or protective atmospheres have to be used. Such metals are
beryllium,
chromium,
magnesium,
titanium, and some
aluminium alloys. Fluxes for high-temperature soldering differ from the fluxes for use at lower temperatures. At higher temperatures even relatively mild chemicals have sufficient oxide-disrupting activity, but the metal oxidation rates become fairly high; the barrier function of the vehicle therefore becomes more important than the fluxing activity. High molecular weight hydrocarbons are often used for this application; a diluent with a lower molecular weight, boiling off during the preheat phase, is usually used to aid application. Common fluxes are
ammonium chloride or
resin acids (contained in
rosin) for soldering
copper and
tin;
hydrochloric acid and
zinc chloride for soldering
galvanized iron (and other
zinc surfaces); and
borax for
brazing, braze-welding
ferrous metals, and
forge welding.
Organic fluxes Organic fluxes typically consist of four major components: •
Activators – chemicals disrupting/dissolving the metal oxides. Their role is to expose unoxidized, easily wettable metal surface and aid soldering by other means, e.g. by exchange reactions with the base metals. • Highly active fluxes contain chemicals that are corrosive at room temperature. The compounds used include metal
halides (most often
zinc chloride or
ammonium chloride),
hydrochloric acid,
phosphoric acid,
citric acid, and
hydrobromic acid. Salts of
mineral acids with
amines are also used as aggressive activators. Aggressive fluxes typically facilitate
corrosion, require careful removal, and are unsuitable for finer work. Activators for fluxes for soldering and
brazing aluminium often contain
fluorides. • Milder activators begin to react with oxides only at elevated temperature. Typical compounds used are
carboxylic acids (e.g.
fatty acids (most often
oleic acid and
stearic acid),
dicarboxylic acids) and sometimes
amino acids. Some milder fluxes also contain halides or
organohalides. •
Vehicles – high-temperature tolerant chemicals in the form of non-volatile liquids or solids with suitable melting point; they are generally liquid at soldering temperatures. Their role is to act as an oxygen barrier to protect the hot metal surface against oxidation, to dissolve the reaction products of activators and oxides and carry them away from the metal surface, and to facilitate heat transfer. Solid vehicles tend to be based on natural or modified
rosin (mostly
abietic acid,
pimaric acid, and other
resin acids) or natural or synthetic
resins. Water-soluble organic fluxes tend to contain vehicles based on high-boiling
polyols -
glycols,
diethylene glycol and higher polyglycols, polyglycol-based
surfactants and
glycerol. •
Solvents – added to facilitate processing and deposition to the joint. Solvents are typically dried out during preheating before the soldering operation; incomplete solvent removal may lead to boiling off and spattering of solder paste particles or molten solder. •
Additives – numerous other chemicals modifying the flux properties. Additives can be
surfactants (especially nonionic),
corrosion inhibitors,
stabilizers and
antioxidants,
tackifiers,
thickeners and other
rheological modifiers (especially for
solder pastes),
plasticizers (especially for flux-cored solders), and
dyes.
Inorganic fluxes Inorganic fluxes contain components playing the same role as in organic fluxes. They are more often used in brazing and other high-temperature applications, where organic fluxes have insufficient thermal stability. The chemicals used often simultaneously act as both vehicles and activators; typical examples are
borax,
borates,
fluoroborates,
fluorides and
chlorides. Halogenides are active at lower temperatures than borates, and are therefore used for brazing of aluminium and magnesium alloys; they are however highly corrosive.
Behavior of activators The role of the activators is primarily disruption and removal of the oxide layer on the metal surface (and also the molten solder), to facilitate direct contact between the molten solder and metal. The reaction product is usually soluble or at least dispersible in the molten vehicle. The activators are usually either acids, or compounds that release acids at elevated temperature. The general reaction of oxide removal is: :Metal oxide + Acid → Salt + Water Salts are ionic in nature and can cause problems from metallic leaching or
dendrite growth, with possible product failure. In some cases, particularly in high-
reliability applications, flux residues must be removed. The activity of the activator generally increases with temperature, up to a certain value where activity ceases, either due to thermal decomposition or excessive volatilization. However the oxidation rate of the metals also increases with temperature. At high temperatures, copper oxide reacts with hydrogen chloride to water-soluble and mechanically weak copper chloride, and with rosin to salts of copper and abietic acid which is soluble in molten rosin. Some activators may also contain metal ions, capable of exchange reaction with the underlying metal; such fluxes aid soldering by chemically depositing a thin layer of easier solderable metal on the exposed base metal. An example is the group of fluxes containing
zinc, tin or cadmium compounds, usually chlorides, sometimes fluorides or fluoroborates.
Inorganic activators Common high-activity activators are
mineral acids, often together with halides, amines, water or alcohols: •
hydrochloric acid, most common •
phosphoric acid, less common, use limited by its polymerization at higher temperatures Inorganic acids are highly corrosive to metals even at room temperature, which causes issues during storage, handling and applications. As soldering involves high temperatures, compounds that decompose or react, with acids as products, are frequently used: •
zinc chloride, which at high temperatures reacts with moisture, forming
oxychloride and
hydrochloric acid •
ammonium chloride, thermally decomposing to ammonia and hydrochloric acid •
amine hydrochlorides, decomposing to the amine and hydrochloric acid ==Rosin fluxes==