Archive for the ‘Process’ Category

Mfg. Considerations when Implementing VOC-Free Flux

Tuesday, August 18th, 2015

Clean Air Act
In 1990 the United States Environmental Protection Agency Issued the Clean Air Act. The
Clean Air Act and subsequent amendments are designed to limit the use of chemicals that
contain volatile organic compounds (VOCs). The document goes into great detail setting limits
for allowable VOC emissions for different industries.

Manufacturers and assemblers of printed circuit boards fall into the category of manufactures
which are allowed to emit up to 15 pounds of VOC emissions per day per manufacturing site.
This limit considerably lower than most of the larger manufacturing cites emit at this time. 15
pounds is approximately equivalent to two gallons of flux or flux thinner.
Presently the US EPA does not have the resources to enforce these amendments, however
that will change in time. As in the case of eliminating CFCs the US EPA acted swiftly and within
a matter of a few years these materials have disappeared from the market completely. The
same or a similar process will soon be used to eliminate VOC containing materials.
Conscientious manufacturers are currently looking at VOC-free technology to replace their
existing flux chemistries.

Solvent Characteristics
Manufactures who have looked at VOC-Free fluxes have discovered that VOC-free fluxes
are not simply “drop in” replacements for the existing flux chemistries. Because VOC-free
fluxes contain water as a solvent difficulties are encountered when soldering boards with these
fluxes.

The difference between VOC-Free and alcohol based fluxes lies in the characteristics of the
solvent (thinner).

The alcohol used in fluxes typically boils at 65-70oF. Existing wave solder machines were
developed to quickly and efficiently flash off the alcohol from the flux.
Water on the other hand boils at 212oF. Most equipment was never designed to provide the
amount of heat necessary to flash off water. Another characteristic of water evaporation is that
a layer of air supersaturated with water forms over the surface of the water when it is heated (Fig. 1).
Because of the increased boiling temperature the solvent evaporation is considerably slower
for VOC-free fluxes. As a result much of the solvent (water) is carried along to the solder pot.
When water touches molten solder it vaporizes with explosive force. The vaporization causes
noticeable spattering and splashing of both flux and solder across the board or assembly. This
result in a multitude of defects on the finished assembly. The majority of defects include solder
balls, solder webbing, incomplete fillets and icicles.
In order to minimize the spattering problem the manufacturer must find a way to drive off the
water during the pre-heat stage of the soldering process.
At first, the task of driving off excess water seems like a simple one. Either by slowing down
the convey or increasing the pre-heat or a manufacturer should be able to accomplish this goal.
Unfortunately it is not that easy. Lets examine these two options.

First, slowing down the conveyor. Slowing down the conveyor will allow the board to see
more heat and subsequently drive off more water but there is a problem. The problem is that
fluxes work best at recommended conveyor belt speeds typically in the 4½ to 6 feet per minute
range. Slowing down the conveyor often results in the manufacturer seeing an increase in
solder related defects such as bridging and the formation of icicles.

The second option is to increase pre-heat. Again this will allow the board to see more heat
and subsequently drive off more water but here too there is a problem. As water is heated it
does not simply go away. What happens is that a supersaturated layer of air is formed just over
the surface of the water, or in this case flux, which acts to inhibit further evaporation.
What is needed is an increase of air flow across the surface of the circuit board to push the
supersaturated layer of air away which will in turn allow more water (flux) to evaporate.
The following section is addressed at modifications that can be made to existing equipment
in order to evaporate off as much water as possible which will in turn allow for fewer defects in
the soldered assemblies.

A Process Modification Suggestion
VOC-Free fluxes can be applied to circuit boards by spray, dip or foaming equipment.
Foaming fluxes will provide a uniform head of small bubbles. The flux level should be
maintained at approximately 1-1.5 inch (2.5 – 3.8 cm) above the stone in the foam fluxer. Note
that this height is twice as high as is normally required for non VOC-free fluxes. It may be
necessary to decrease the width of the foam chimney to achieve the higher foam heights.
An air knife after the flux tank is recommended to remove excess flux from the circuit board
and prevent dripping on the preheater surface. A warm gentle airflow is required so as not to
blow the flux off the board.
The optimum preheat temperature for most circuit assemblies is 200 – 240°F (93 – 116°C) as
measured on the top or component side of the printed circuit board.
The wave soldering speed should be adjusted to accomplish proper preheating and to
evaporate the water to eliminate spattering. Typically, speeds of 4½ to 6 feet per minute are
used. The surface tension of the flux has been relieved to cause the flux to form a thin film on
the board surface to allow flashing off of the water.
VOC-Free fluxes are water based and because of this, splattering is a problem. Splattering
occurs when a board that is still wet comes in contact with molten solder. One way to drive off
the water is by using forced air or convection in the pre-heat zone. Blowing hot air at 10-30
cubic feet per hour greatly assists in drying the water off the circuit boards. Copper or stainless
steel tubing is placed down on the preheaters and several holes are drilled in the tubing, these
holes act as air knives to evaporate the water. See figure 2. The holes closest to the fluxer are
angled at 45° back to the fluxer. These air jets act like an air knife and help minimize the
amount of flux that is carried by the board. The holes further away from the fluxer are angled at
90°. (Fig. 3). These air jets help dry the flux out from the through-holes.
Another potential problem area is in the area of the pallets for the boards. A pallet with
fingers is preferred to a pallet that completely encloses the board or boards. The fingers are
important to let the excess flux drain before the pallet hits the molten solder. Some
manufacturers have found that drilling drain holes along the trailing edge of the pallet is enough
to ensure good flux drainage.

Conclusion
The successful implementation of VOC-free flux technology requires some process
modification for most of the existing wave soldering equipment. An increased air flow across
the circuit boards is needed to drive off most of the water present in VOC-free fluxes. The
purpose of this paper has been to present a modification that can be installed onto existing
equipment to help drive off the excess water. The suggested network of tubing is easy to
assemble and easy to retrofit onto existing equipment.

Source: David Scheiner, Senior Technical Service Engineer Kester Solder

No-Clean Flux Thinning

Tuesday, August 18th, 2015

No-Clean Flux ThinningSoldering fluxes loose solvent and need additions of thinner. Flux is composed of solids dissolved in a solvent base. Over time the solvent evaporates. As the solvent evaporates the solids concentrate and eventually crystallize out. You will need to add thinner on a regular basis to prevent the flux from crystallizing. A hydrometer is used to measure the specific gravity of the flux. Normally the specific gravity (density) is checked 2 or 3 times a day. Thinner is then added to return the flux to its correct density. Hydrometers can be purchased from any scientific supply house. Kester has flux density control Data Sheets (also called nomographs) for the rosin and higher solid content fluxes. Using the nomograph you can determine how much thinner needs to be added. We sell test kits for the low residue fluxes. The test kits indicate how much thinner to add to the flux pot. Source: Kester Solder Co.

Removing Organic Acid (OA) Flux Residues

Tuesday, August 18th, 2015

It is required to remove the residues of OA fluxes? You will get corrosion if you do not fully remove all the flux residues. The flux residues from organic fluxes are hygroscopic, they contain organic acids and they may contain halides. Over time the residues will absorb moisture and the halides will become mobile and corrosive. This will lead to ‘catastrophic failure’ of the assembly in question. We recommend cleaning with an aqueous cleaning system, it can be either batch type or in-line. The water temperature should be between 120-140°F. The important thing is to have lots of rinsing and flushing to completely remove all the flux residues.

Lead Free Reflow Profile Chart

Monday, August 17th, 2015

Lead-Free-Reflow-Profile-Chart

Pin Holes: Pin holes often appear on the surface of solder joints. How are they formed?

Friday, August 14th, 2015

Pin holes are formed as a result of moisture entrapment. All that is required is a tiny amount of moisture. When the solder comes in contact with the through-hole, component lead, wire or whatever is being soldered, the water boils and it forms a gas bubble that will either escape or be trapped as the solder solidifies

Soldering Thermocouple Wires : Thermocouple wire materials are not solderable

Friday, August 14th, 2015

Thermocouple materials are not solderable. It is possible to surround the thermocouple wire (encapsulate it) with solder but you cannot make a metallurgical bond to it. It is important to note that even if you could solder the two wires back together the thermocouple still will not work. A thermocouple works by measuring the change in resistance of the two dissimilar metals joined in the welded bead. If one were to join the metals with a solder inter-connect the thermocouple would give meaningless numbers. The way to fix a broken thermocouple is to re-weld the thermocouple bead. If you wish to attach a thermocouple to a printed circuit board for reflow profiling, you can use a high temperature alloy to encapsulate it or use a cyano-acrylate adhesive to stick it to the board.
Source: Kester Solder Co.

Green Corrosion? Rosin Fluxes react with copper.

Friday, August 14th, 2015

Green Corrosion? Rosin fluxes react with copper.
Got green corrosion? Rosin fluxes react with copper (especially on braided cables underneath the insulation) to form a green by-product that is not corrosion.

In many applications where soldering is done with an excessive amount of rosin flux there appears on the copper surface a green residue similar to corrosion.

Chemical Reaction
Commercial water-white rosin consists of about 80% sylvic (or abietic) acid. The balance is other isomeric forms of diterpene organic acids which do not enter into the reaction of soldering. Abietic acid when heated combines directly with the oxide on the copper surface, yielding a copper abietate. This is the green, soapy looking material which resembles corrosion products of copper. The formation of copper abietate is noticed readily on wire under clear Teflon for two reasons. First, simply because the clear Teflon can be seen through. Second, because the Teflon during soldering rapidly expands and contracts, thus trapping the rosin with some ionizing solvent under the insulation. The abietic acid does not attack the copper metal under any condition. This abietate formation is peculiar to copper surfaces since the only common abietate salt is of copper.

Activated Fluxes
Most soldering applications require a more active flux in order to clean the surface oxide. Activated rosin fluxes contain small quantities (0.2% to 5%) of organic activating agents. The purpose of these activators is to catalyze the rosin copper
oxide reaction so that a better soldering job can be obtained. The catalytic agents do not enter into the reaction and do not cause subsequent corrosion. However, the presence of these activators does impel the rosin (abietic acid) to combine with the copper oxide to form the green copper abietate compound. Copper abietate is not conductive and forms a green insulating coating on copper. Usually the dark rosin residue conceals this normal formation of green copper abietate.

Solution to the Problem
Concern develops over the green residue because copper abietate cannot readily be distinguished from corrosion products of copper. The degree to which the flux is activated has little bearing on the problem. The activators are still present in
sufficient quantity to trigger the copper abietate formation. The best way to minimize the green residue is to use copper with a minimal amount of oxidation. Reducing the amount of rosin flux used will also minimize the amount of residue.

Source: Kester Solder Co.

White Residue: Identification and categorization of white residues often found on cleaned circuit assemblies.

Friday, August 14th, 2015

White Residue: Identification and categorization of white residues often found on cleaned circuit board assemblies.
Abstract

White residue remaining after cleaning circuit board assemblies can be caused by a variety of chemicals and reactions. Rosin and water-soluble fluxes, circuit board resins and epoxies, component materials and other contamination all contribute to this complex chemistry. This paper discusses many of the sources of the residues that seem to be an ever-increasing
occurrence.

What is this white residue on the printed circuit assemblies? Why is the white residue suddenly appearing when it never happened before? What is causing the white residue? Why is this only and intermittent problem?

These are questions accompanying soldered circuit board assemblies sent to the Kester laboratory for analysis and, hopefully, some answers. The residue remains after cleaning the assembly to remove soldering flux.

The problem is not limited only to rosin fluxes and solvent cleaning, but also occurs when water soluble fluxes are used and when either flux type is removed with water. The soldering and cleaning processes involve so many chemicals in the flux, circuit board, components and cleaning agents that a complete understanding of the reactions is very difficult if not impossible.

There are white residue problems with water soluble fluxes and many of the causes not related to the flux compositions are the same as for rosin fluxes. The organic water soluble flux itself is more likely to oxidize and decompose than a rosin flux because generally the water soluble organic acids are not as heat stable as rosin acids. Halide (chloride and bromide) salts help reduce oxidation and improve activity but may result in heat of soldering may also no be removed with water.

Rosin Flux more often has been used for electronic assemblies when the white residue problem arises. If rosin fluxes appear to be such a problem, why continue to use them? The answer is simple. Rosin fluxes are active enough to solder electronic assemblies and the residue has a very good insulation resistance. Typically rosin fluxes, including most
activated types, have insulation resistances in the 1010 ohms or higher. The problem arises when it is required to remove the residue either because the assembly will operate hot (above 65̊C) where the rosin becomes tacky, or the rosin might flake off and get between electrical contacts or just for aesthetics (not a good reason for cleaning).

Rosin is derived from pine trees. Gun rosin essentially is pine tree sap that has had approximately 20% turpentine distilled off. What remains is gum rosin. Wood rosin is obtained by boiling aged tree stumps. Tall oil rosin is a byproduct of the paper pulping process. Wood and tall ail rosin are similar to gum rosin but contain a different mixture of
resin acids.

Oxidation of the rosin during heating involves the double bonds of the resin acids. The conjugated double bonds of the abietic type acids are particularly susceptible to oxidation by atmospheric oxygen because of the unsaturation. The reaction is one of oxidation, resulting in peroxides, hydroxy and keto compounds. The oxidized rosin is considerably less soluble in solvents than the original rosin and after cleaning a circuit board assembly, remains irregularly distributed over the surface as a white film. The most common type of circuit board on which this residue appears is the thick multilayer with ground planes . The excessive amount of heat required (heat is temperature for a time) results in oxidation of
the rosin.

The overheating, usually exceeding 150̊C, often has been said to cause polymerization of the rosin. There possibly is some formation of epoxide but polymerization is not likely to occur to any measurable extent at the soldering temperature (250̊C) and without the presence of a catalyst.

This oxidation can be minimized by hydrogenating the resin acids to reduce the unsaturation. However, the soldering ability of the rosin is considerable reduce. This oxidized rosin appears to be the most common “white residue” appearing on soldered circuit boards. Chlorinated of fluorinated solvent, alcohols and saponifier/water cleaning seem to have little effect for removing this residue.

An industry “magic” method for removing this white residue, when it appears, has traditionally been to run the circuit board assembly across only the fluxer and preheater and remove it prior to soldering. Then when the assembly was cleaned in the normal manner, the white residue often would disappear. There is really nothing magic about the success of their process. If this white residue is oxidized rosin, melted resin acids should be a good reactive solvent to help remove the residue. In the laboratory evaluation, if the residue appear to be a film, sometime removable by wiping with a cloth, e have also used other acidic solutions to remove it. An alcohol-based organic acid flux is very effective in solubilizing the white reside. Also, other mild acidic solutions such as solder brightener have worked. A thirty second dip in these solutions followed by a 50:50 alcohol: water rinse usually removes the residue. This points directly at the rosin as the source. However, infrared, ultraviolet and HPLC analysis of the various lots of rosin show no chemical difference between a flux that leave white residue and one that does not.

The acid carboxyl group also reacts during soldering. Because tin can also be detected in the white residue, a portion (less than 10% by observation) of the reside may be a reaction product between tin oxide and the resin acids. The result is often referred to as tin abietate instead of tin resinate which is more correct since the resultant compound is informed also with the pimaric acids. The salts of pimaric and dehydroabietic acids are very insoluble in water or alcohol while those of abietic neoabietic and isopimaric acids are more soluble.

This reaction with metal oxides or hydroxides is slow because of molecular structure hindrance of the resin coaboxylic acid group.

Esterification of the resin carboxyl group also is difficult because of steric hindrance, but at
soldering temperature (250̊C) the presence of glycol can result in resinate formation. Rosin esters are used in lacquers for wood finishing, adhesive and even chewing gum. The diverse selection of chemicals added to rosin fluxes can result in a number of residues which may be difficult to remove.

Activators which consist of halides (chlorides or bormides) and halogens capable of liberating halides also can result in white residues.

The halide activator improves the ability of the flux to remove metal oxides and also improve the heat stability of the rosin. However, the tradeoff is the type of residue that can result. Type R (plain rosin) and type RMA (small amount of halide) fluxes are more susceptible to oxidation. Type RA (0.1 0 0.5% halide) are more heat stable but can leave halide salts. Rosin with its high insulation resistance keeps the halides dormant but if the rosin is remove, leaving some halide salt behind, corrosion is possible.

Lead chloride can form as an insoluble white residue on the solder surface. In the presence of moisture and carbon dioxide in the air, lead carbonate can form The liberated hydrochloric acid continues the corrosion cycle until a large growth of lead carbonate has occurred. This is more common with water soluble fluxes containing chloride but has been known to occur with highly activated rosin fluxes which have been incompletely removed. Typically if the white residue is on the solder, if a piece of wetted silver chromate test paper is placed on the residue for a minute, chloride or bromide can be detected by a change in the color of the paper from tan to white (chloride) or yellow (bromide). Most commonly copper salt is green and the white reside turns out to be lead chloride/carbonate salts. The lead chloride is not soluble enough to be removed with water and appears as a
film on the solder.

Solvent (chlorinated or fluorinated) can be a source of chloride residue. Inhibitors are added to help prevent degradation or “souring”, but in the presence of chlorides from flux and water from condensation the solvent can “go acid” and cause chloride formation.

Solder mask is also a major cause of white reside. Incompletely cured solder mask can be
the result of formulation error, lack of heat for infrared cured type or ultraviolet cured type. Most solder mask related whit reside seems to be with the UV curable type, possibly because that is more prevalent or there really are control problems in applying it. Improper cure can be for simple reasons, the greatest being associated with the UV lamps. We have seen 15-20% difference in intensity from lamp to lamp. reflectors get dirty, and lamps wear out or get out of focus. The coating thickness also affects the cure. Soft solder mask can result in attack by the flux or cleaning chemicals. The best cure for UV solder mask seems also to include a thermal cycle. If the soldering process provides this heat to set up the mask, rosin or solder (as small spheres) can get stuck in the mask epoxy. Contamination under the solder mask can cause mealing or blistering of the mask,sometimes appearing to be residue. Over cured solder mask can crack, and if the mask was over solder plating, small solder spheres can extrude out to the surface. Solder mask usually is colored probably to see if it is there and to cover any blemishes on the circuit
board. We have seen examples where the color has washed out of the mask, resulting in what looks like white residue.

Laminate also might be incompletely cured either because the board manufacturer made a
mistake or the resin was misformulated. A typical thermosetting epoxy resin (FR-4) is based on the reaction between epichlorohydrin and tetrabromobisphenol A. The bromine is added for fire retardance. It is possible without complete cure of the epoxy for the carboxylic acid in the rosin to react with both the epoxy group and a hydroxyl group to form
esters. Another possibility for white residue.

The brominated dihydric phenol thermally degrades at only 135̊C. Without complete thermoset cure and with the rapid heating of soldering, it is possible for the hydrochloric acid in the flux (even type RMA) to attack, liberate the bromide and form lead bromide on the solder surface. This is another insoluble white residue.

Gray residue can wash up out of plated through holes to appear on the top of circuit board. This material may be organic additive in the solder plating in the holes or on the component leads. Another possibility is etching chemicals left in the holes.

Protective coatings on copper surfaces vary considerably in composition and, unfortunately, everybody assumes that this coating is compatible with the flux and cleaning agents. With increasing interest in solder mask over bare copper (SMOBC) if the copper is not solder coated, a “protective” coating is applied to minimize oxidation of the copper
during storage and handling. A good example of a residue problem is the use of a rosin protective coating on a board which is soldered with water soluble flux and cleaned in plain water. Some alkaline saponifier added to the water will help remove this residue.

Water cleaning results in some other residue problems. The surfactants used in the water
soluble flux may not dissolve in water that is either too hot or too cold. This is usually not a white residue but the “invisible” residues may be even worse as they are usually conductive. If the alkaline saponifier is too concentrated or too active, the solder on the circuit board assembly can be oxidized. This white or tan residue is not residue at all, but in the right light, it appears to be a film, the film, being tin oxide. Any aluminum fixtures or
parts going through the alkaline saponifier will be attacked. The aluminum can be coated with a white reaction product and, in the case of aluminum fixture, the white residue can transfer to the circuit board assembly. The water itself can contain enough cadmium, magnesium or iron salts if harder than 4 grains of hardness to leave a white residue. Even
if the water is softened there may be sodium salts that could remain after water washing a circuit board assembly.

Component residues may be material like wax on transformers and capacitors or lubricating oil from switches. These residues are only remaining because nobody considered if they were able to be removed with the cleaning chemicals.

Melted components is not a residue but we have received components or circuit boards with “white residue” problems. Three examples are:-

– A connector with the plastic body made of glass filled polyester. The literature said the connector could withstand 125̊C. Of course the leads were being dip solder coated at 250̊C. The hot rosin in contact with the plastic was melting it, turning it white.

– A flat pack surface mounted chip carrier was being soldered with a heated bar and solder paste to and epoxy-glass circuit board. The combination of heat and pressure and incompletely cured epoxy degraded the epoxy. This looked like white residue between the component leads.

– Soft plastics such as polycarbonates are attacked by chlorinated solvents. Hard rosin residue is most easily removed with the same solvent. Sometimes the white residue is actually solvent attack on the plastic.

Conclusion
the sudden appearance of white residue on circuit board assemblies after cleaning indicates that something in the soldering/cleaning process has gone out of control. The variety of chemicals, the similarity of materials (rosin vs. resin), the instability of solvents and changing heat could all enter into the creation of white residue. Reactions and
stability of the rosin causes most of the residue, but board and component materials can also contribute to the problem.
It is time consuming to evaluate all of the possibilities but quite often a quick chemical test or microscopic examination can determine the nature of the “residue” or in fact, if it even is a residue.

Source: Dennis F. Bernier, Vise President, Research & Development; The Nature of White Residue on Printed Circuit Assemblies, April, 1988

Gold Colored Solder: Assemblers are often concerned when they see a gold color on the surface of a solder pot.

Friday, August 14th, 2015

The gold color is tin oxide. When the surface of the molten solder is exposed to air it oxidizes and turns gold; sometimes the tin oxide is a purple-blue color. This is normal and can only be prevented by using an anti-oxidant powder or pellet. The discoloration is a cosmetic defect and in no way degrades the reliability of the solder. Kester offers the #5744 Dross eliminator for this purpose.
Source: Kester Solder

Sn60 vs. Sn63: When is the use of one of these two alloys more appropriate than the other?

Friday, August 14th, 2015

The Sn60Pb40 has a plastic range and puts down a slightly thicker coating of solder. Sn60 is often preferred for lead tinning and other solder coating applications. Sn63Pb37 is eutectic and as such has no plastic range. Generally it flows better than the Sn60 and is the preferred alloy for wave soldering and surface mount applications.