Archive for the ‘Process’ Category

CircuitWorks Silicone Free Heat Sink Grease CW7270

Wednesday, August 19th, 2015

Frequently Asked Questions

Circuitworks® Silicone Free Heat Sink Grease, CW7270

1. What is heat sink grease?
Circuit boards produce large amounts of heat that has to be transferred from the components in order to prevent damage. This heat is usually removed by a heat sink, a component attached to the microprocessor. The better the contact between the processor and the heat sink, the faster and more efficiently the heat transfer will occur. Heat sink grease facilitates heat transfer away from electrical/electronic components by filling the voids between the surface of the component and the surface of the heat sink. The heat sink grease is produced from materials that allow heat to pass through them quickly, a quality known as thermal conductivity. These materials are blended into grease that fills the voids to improve heat transfer.

2. What is the difference between a silicone and non silicone heat sink grease?
The obvious difference is that one product contains silicone oil and the other doesn’t. Greases are made with oils and other compounds to impart the proper performance characteristics. Silicone heat sink grease contains silicone oil, which provides excellent performance in situations where high temperature stability is required. However, silicone oil can bleed from the heat sink compound, resulting in a number of negative results. The silicone oil can prevent coatings from adhering to the surface and cause insulation of contacts. It can also promote high dust accumulation. Circuitworks® Silicone Free Heat Sink Grease is formulated with an oil that provides the high temperature stability without the negatives associated with silicone-based heat sink greases.

3. How do I use heat sink grease?
Make sure the area for grease application in clean and dry. Apply a small amount of the grease to the bottom of the heat sink and spread evenly, and attach the heat sink. Remember to use as little as possible, as using too much can decrease the efficiency of the heat sink.

4. What are its features and benefits?

Features:
• Excellent thermal conductivity
• High dielectric strength/not electrically conductive
• Exceptionally low bleed

Benefits:
• Rapidly transfers heat from surfaces and components
• Will not short components
• No creep or migration over a wide temperature range

5. Does Circuitworks® Silicone Free Heat Sink Grease meet MIL-DTL-47113D, Type II?
Circuitworks® Silicone Free Heat Sink Grease exceeds the MIL-DTL-47113D Type II performance specifications.

6. How is the product packaged?
The product is packaged in a convenient syringe containing 7 grams of grease.

CircuitWorks Nickel Conductive Pen, CW2000

Wednesday, August 19th, 2015

Circuitworks® Nickel Conductive Pen CW2000

1. What is the Circuitworks® Nickel Conductive Pen and what does it do?
The Circuitworks® Nickel Conductive Pen is the convenient to use pen that makes instant conductive traces and coatings on circuit boards, plastic enclosures, etc. It’s good for linking components, repairing defective traces and making smooth jumpers in cost effective systems. It is also ideal for providing EMI/RFI shielding for electronic components.

2. What’s the difference between the Circuitworks® Conductive Pen and the Circuitworks®
Nickel Conductive Pen?
The Circuitworks® Conductive Pen contains a silver-based compound that is designed for the highest level of conductivity. This product is designed for circuit boards that require the most conductive trace possible. Because of the high silver content, this silver-based Conductive Pen could be cost prohibitive for some repair applications. The Nickel Conductive Pen contains nickel as its conductor. While nickel is not as conductive as silver, it does provide good conductivity for less critical repair work. It is a cost effective alternative to silver-based conductive inks. It does contain the same polymer package as our other conductive pens, so cure times are approximately the same.

3. How electrically conductive is the Circuitworks® Nickel Conductive pen in comparison to
the Circuitworks® Silver Conductive Pen?

The silver-based Circuitworks® Conductive Pen possesses a higher electrical conductivity than the Circuitworks® Nickel Conductive Pen. The conductivity is 0.02 – 0.05 ohms/sq/mil for the Circuitworks® Conductive Pen and 1.0-1.5 ohms/sq/mil for the Circuitworks® Nickel Conductive Pen.

4. What are its features and benefits?

Features:
• Single component system
• Good electrical conductivity
• Fast drying
• Highly adherent to most materials
• Low cost

Benefits:
• Easy application
• Repairs damaged circuits & shielding
• Tack free in 3 to 5 minutes
• Bonds well to circuits and housing components
• Economical solution for conductive requirements

5. How do I use the Circuitworks® Nickel Conductive Pen?
Make sure your board is clean and dry for the best adhesion. We recommend Chemtronics Electro-wash® PX Cleaner/Degreaser to remove any surface contamination that might prevent good material contact. Shake the pen vigorously for 30 seconds to insure proper dispersion of the nickel flakes. Squeeze the pen while pressing down on the surface to begin the flow. Draw the trace along the desired path. It’s best to practice with the pen before attempting detail work.

6. How long does it take the trace to dry?
The Nickel Conductive Pen trace will be tack free in 3 to 5 minutes at room temperature. Electrical conductivity is achieved within 30 minutes. You can heat cure the trace for 10-15 minutes at 80ºC to 100ºC for maximum durability and chemical resistance.

7. Does the Circuitworks® Nickel Conductive Pen require an overcoat to protect it after
it is cured?

The trace created by the Nickel Conductive Pen does need protection after curing. We recommend our Circuitworks® Overcoat Pen for the best results.

8. Can I solder to the trace of the Circuitworks® Nickel Conductive Pen?
The trace created by the Nickel Conductive Pen is not solderable. If your application requires soldering after the trace is cured, try CircuitWorks Silver Conductive Pen. It is solderable at low temperatures.

9. What is the shelf life of the Circuitworks® Nickel Conductive Pen?
Twelve (12) months from the manufacturing date stamped on the container.

CircuitWorks Flex Conductive Pen CW2900

Wednesday, August 19th, 2015

Frequently Asked Questions

Circuitworks® Flex Conductive Pen, CW2900

1. What is the Circuitworks® Flex Conductive Pen and what does it do?
The Circuitworks® Flex Conductive Pen makes instant, highly adherent silver traces on flexible polymeric substrates, such as Mylar and Melinex. It’s ideal for linking components, repairing defective traces and making smooth jumpers. The Flex Conductive Pen
traces also have excellent adherence to Indium Tin Oxide (or ITO).

2. What’s the difference between the Circuitworks® Conductive Pen and the Circuitworks® Flex Conductive Pen?
The Circuitworks® Conductive Pen is designed for standard circuit board repair. Its silver traces dry in minutes and have excellent adhesion to most rigid electronic materials. Flexible circuit boards are constructed with materials that allow flexibility while
retaining conductivity. The different composition of the dielectric substrates used require a different type of conductive trace, one that can adhere to these materials, contain the flexibility of the substrates and have excellent conductivity. The Flex Conductive Pen
matches these requirements in an easy to use package.

3. What are its features and benefits?
Features:

• Single component system
• Highly adherent
• Flexible polymer composition
• Excellent electrical conductivity
• Fast Drying

Benefits:
• Easy to use, no mixing
• Bonds to ITO, Mylar and Melinex
• Retains conductivity after bending
• Good for repairing defective traces
• Tack free in 5 minutes

4. How do I use the Circuitworks® Flex Conductive Pen?
Make sure your board is clean and dry for the best adhesion. We recommend Chemtronics Electro-Wash® PX Cleaner/Degreaser to remove any surface contamination that might prevent good material contact. Shake the pen vigorously for 30 seconds to insure proper dispersion of the silver flakes. Squeeze the pen while pressing down on the surface to begin the flow, then draw the trace along the desired path. It’s best to practice with the pen before attempting detail work.

5. How long does it take the trace to dry?
The Circuitworks® Flex Conductive Pen trace will be tack free in 5 minutes at room temperature. Electrical conductivity is achieved within 15 minutes. You can heat cure the trace for 15 minutes at 80ºC to 90ºC for maximum durability and chemical resistance.

6. How electrically conductive is the Circuitworks® Flex Conductive Pen in comparison to the Silver Conductive Pen?
The coatings provided by both the Circuitworks® Flex Conductive Pen and the Silver Conductive Pen exhibit excellent conductivity.
The conductivity measures 0.05 – 0.15 ohms/sq/mil for the Circuitworks® Flex Conductive Pen and 0.02-0.05 ohms/sq/mil for the Silver Conductive Pen.

7. What is the shelf life of the Circuitworks® Flex Conductive Pen?
Twelve (12) months from the manufacturing date stamped on the container.

Source: ITW Chemtronics

Chemask NA Non-Ammoniated Solder Mask

Wednesday, August 19th, 2015

Frequently Asked Questions
Chemask® NA Non-Ammoniated Solder Mask

1. What is Chemask® NA? What are its features and benefits?
Chemask® NA Non-Ammoniated Solder Masking Agent is a fast curing, peelable temporary spot mask formulated for safe use on
sensitive metals. It contains high-temperature resistant compounds that protect component-free areas during wave soldering.
Chemask® NA may also be used to protect pins, posts, contacts and edge connections in the solder reflow oven or during
conformal coating processes.

• Stable to 550°F (288°C) – withstands lead-free processing temperatures
• Ideally suited for use with gold, copper, nickel, silver and OSP finishes
• Works with both lead-free and tin/lead applications
• Phthalate-free, low toxicity and environmentally safe
• Compatible with all flux types and cleaning solvents
• Dries tack free in 15 minutes (10 mil thick application)
• Can be introduced into the pre-heat oven without being fully cured
• Removes easily by hand and leaves no residue
• Non-contaminating, non-staining and non-corrosive on all surfaces
• RoHS compliant

2. How does the new Chemask® NA compare to the latex peelable mask Chemask® CM8?
Chemask® NA is also a peelable mask and works as well as Chemask® CM8. The primary differences are that Chemask® NA does
not contain ammonia, and is therefore compatible with lead-free board finishes such as immersion silver, immersion gold, nickel,
lead-free HASL and Entek. Chemask® NA can also be used on standard tin/lead board finishes, including bare copper. Chemask®
NA will also withstand hotter processing temperatures and longer cycling times than any other mask on the market today.
Chemask® NA is not as elastic as Chemask® CM8, which tends not to be a problem with most electronic applications. For other
applications, it can be used successfully on a variety of non-porous surfaces.

3. How do I use Chemask® NA?
When applying the mask by hand using 8 oz. squeeze bottle, insure that all areas of the pre-tinned hole or pad are evenly covered
on the side to be soldered. Automatic dispensing equipment may also be used as appropriate. Chemask® NA can also be applied
using a screen or a stencil. For ease of removal, a minimum thickness of 30 mils is recommended.
Chemask® NA can go straight into the pre-heat oven of a wave soldering machine, or can go into a reflow oven 15 minutes after
application to the PCB. This mask may remain on assemblies for extended periods of time prior to or after processing.
After processing the board, Chemask® NA can be easily peeled off the board by hand or using tweezers.

4. What if I want to apply an extra thick layer of Chemask® NA to the board?
When Chemask® NA is applied in a thick application (> 1/8″), allow extra drying time or oven dry at 250ºF for 30 minutes.

5. If I put Chemask® NA into the pre-heat oven after a short 15 minute cure time, won’t
bubbles form in the mask?

No. Chemask® NA will withstand preheat temperatures without degradation or distortion of the film and will be completely cured by
the end of the processing cycle.

6. Is Chemask® NA completely non-flammable?
Yes. Chemask® NA is non-flammable and contains no flammable components.

7. Is Chemask® NA safe to use?
Yes. Chemask® NA has no strong odors, is non-toxic and, unlike competitors’ products, does not contain phthalates.

8. Is Chemask® NA RoHS compliant?
Yes. RoHS certificates are available on the Chemtronics website www.Chemtronics.com.

9. Is Chemask® NA environmentally friendly?
Yes. Chemask® NA contains no VOC’s or other harmful volatile components. After it has been cured, Chemask® NA can generally
be disposed of without any worries about hazardous waste generation.

10. How can I tell if the product I am using is Chemask® or Chemask® NA?
Chemask® NA is tinted green while the other peelable Chemask® products (Chemask®, Chemask® HV and Chemask® Lead-Free)
are pink.
11. What is the shelf life of Chemask® NA?
The shelf life is three (3) years from the manufacturing date stamped on the container.

12. What type of companies would be interested in these products?
The primary customers that use temporary solder masks are electronics manufacturers, including OEM and contract
manufacturing companies.

13. How is the product packaged?
Chemask® NA is available in two sizes:
• CNA8 8 oz. squeeze bottle packaged in 24 per case
• CNA1 1 gallon

Source: ITW Chemtronics

Lead Free and PCBs

Tuesday, August 18th, 2015

Printed Wiring Boards

Do the printed wiring boards have to be lead-free?
Estimates are that 60-70% of printed wiring boards are tin-lead solder coated, usually by hot air solder leveling (HASL). The solder coatings are applied to the copper surfaces of the printed wiring board to preserve solderability and protect the copper conductors from environmental corrosion. To comply with European Restriction of Hazardous Substances (RoHS) Directive 2002/95/EC, tin-lead solder cannot be used.
What lead-free finishes are alternatives for tin-lead finishes?
There are many proposed alternatives for tin-lead finishes, none performing equal to tin-lead. Changing to lead-free is not going to be as easy as just changing to another coating. Some alternatives are: •hot air solder leveling (HASL) with lead-free solder, such as tin-silver-copper, tin-silver, or tin-copper
• organic solderability preservatives (OSP) placed on the copper
• immersion tin or bismuth, applied in thin coatings of 1-2 microns, or silver coatings of less than 0.1 micron
• palladium applied electrolessly directly on the copper, or coating the copper with nickel and then palladium
• electroless nickel coated with immersion gold (ENIG)

What problems might be anticipated with lead-free printed wiring boards?
The least amount of problems would be putting no coating on the copper and trying to keep the copper surface clean and active during storage and assembly. The choice of coatings presents different problems. •Hot air solder leveling (HASL) coatings present a problem common also with tin-lead solder, i.e., non-uniform pads causing problems with placement of surface mount components. Also, the lead-free alternatives do not have the same appearance as tin-lead, generally being dull or grainy.
• Organic Solderability Preservatives (OSP) are not very heat-stable. Though barely being able to withstand one heat of soldering, the OSP coating makes soldering very difficult for a second reflow.
• Immersion tin coatings less than 1-micron directly on copper can result in decreased solderability as the copper-tin intermetallics form. This can lead to the formation of tin whiskers erupting out of the tin coating. A nickel coating under the tin can improve solderability and minimize the tin whisker formation.
• Palladium is deposited on nickel over the copper. This is an expensive coating that is used on components but not often on boards.
• Electroless nickel under immersion gold (ENIG) provides a solderable coating, but is expensive. The gold (about 0.1 micron thick) dissolves instantly in the melted solder, and soldering is done to the underlying nickel. The amount of phosphorous deposited with the nickel determines whether the soldering is going to be reliable or not.

Source: Kester Solder co.

Lead Free Component Finishes

Tuesday, August 18th, 2015

In the component finish selection avoid lead bearing finishes. The lead in the finish will dissolve into the lead-free solder. This will cause the formation of lead intermetallic phases with differing physical properties (such as expansion/contraction differences) and differing melting points. Work is ongoing to determine the long-term effects of small amounts of lead on high reliability electronics. For many consumer electronic assemblies such as mobile phones and household electronics, where the thermal cycling and condition of use are not extreme the inclusion of lead in component finishes has not demonstrated any negative characteristics to the solder joint integrity. As Japan and Europe progress with lead-free assembly numerous component finishes are already available without lead. It is important to work closely with component suppliers to insure the lead finish is lead-free compatible, the component molding plastic is able to withstand the higher temperatures associated with lead-free soldering and also the component’s reliability will not be jeopardized with the higher exposure temperatures. •Some common finishes include:
◦NiPd
◦NiPdAu
◦SnB
◦Sn
◦SnCu
◦SnAg
◦Au
◦AgPt

◦More finishes are originating from Asia
•PBGA
◦ With SnAgCu, some issues need to be investigated

•Flip Chip
◦ Patented indium alloy compatible with SnAgCu
◦ Might be exempt

•Molded Components
◦Concern about higher processing temperatures, components are available that sustain the higher soldering temperatures.

•Component Process Consideration
◦ Work closely with component suppliers
◦ Determine component lead-free finish availability
◦ Select best solderable finish and component finish shelf life
◦ Select components with compatible molded plastics and the ability to sustain the thermal requirements of the lead- free process
◦ Material handling logistics, segregate lead-free finished components from leaded components, if using both a lead-free and a leaded assembly process
◦ Insure the components and component feeders are identified as containing lead-free finishes.
◦ Train purchasing, receiving and assembly personnel on the handling procedures to avoid confusion between leaded and lead-free components during the transition stage.
◦ Identify the soldered assembly as lead-free to insure the proper rework of the lead-free components in-house and in the field.

Making Lead-free a Reality

Tuesday, August 18th, 2015

Lead-free fluxes used in solder paste, liquid flux for wave soldering, flux gels and wire solder are available today. These flux systems are designed to enhance the soldering process and are formulated to give excellent solder wetting performance with the added thermal stability of the chemistry, required with lead-free assembly. Traditional fluxes used with tin-lead alloys may not be adequate to circumvent the slower wetting of lead-free alloys and the higher temperatures normally associated with lead-free solders. Flux systems specifically formulated for lead-free soldering will require new activator packages and heat stable gelling and wetting agents to avoid solder defects. Due to the slower wetting and higher surface tension of many lead-free alloys, choosing the right flux for lead-free soldering will prevent the increase of solder defects and greatly assist in maintaining production yields. Typical defects, which can show an increase when transitioning to lead-free assembly are detailed below. These defects can be eliminated with proper flux selection and process control.

• Potential Defect Increase – Lead-free SMT Assembly
Bridging – Paste with poor hot slump behavior
Solder balls – Paste with poor slump properties
Tombstoning – Thermal differences across board
Non-wetting – Excessive preheating or inadequate flux activity
Poor wetting – Poor flux activity or excessive preheating
Solder Voids – Thermal profile too low, or inadequate flux chemistry
Solder beading – Paste with poor hot slump or excessive preheating
Potential Defects Increase – Lead-free Wave Soldering
Bridging – Flux deactivation during preheating or solder contact
Icicling – Flux too low in activity or preheating temperature to high
Solder Balls – Insufficient preheat or flux-solder mask incompatibility
Insufficient Hole-Fill – Flux activity too low, too low solids, or excessive preheat temperature or too low a contact time with molten solder

•Requirements for a Lead-Free Flux:
◦ Low-activation temperature
◦ Adequate shelf life
◦ High activity level
◦ High reliability
◦ Residues benign or easily remove with water if the paste is a water washable type

•Other Considerations for the Lead-free Flux :
◦ Is the paste for dispensing or printing?
◦ Note manufacturers use different types of activators for different alloys
◦ Select flux carefully to balance activation temperature with thermal profile
◦ What is the compatibility of the flux with the alloy selected?
◦ What are the reliability properties (SIR, electro-migration, corrosion)?

Considerations for Lead-free Solderpaste
•Important properties to consider during selection: ◦Solder Balling Test activity
◦ Wetting Test , specific finishes and solder atmosphere (air or nitrogen)
◦ Voiding Potential, lead-free alloys are more prone to solder voids
◦ Tack Life Over Time
◦ Stencil life and abandon time
◦ Cold Slump
◦ Hot Slump tested to higher temperatures 180-185 C ° .
◦ Shelf-life Testing

Properties to evaluate in-process:
◦Printability
◾Relax/Recovery
◾Print Speed
◾Durability

◦ Component Placement
◾ Drop back for tack

◦ Reflow
◾ Examine solder joint formation on a variety of leads and PWB finishes

• Properties to evaluate after reflow
◦ Thermal Shock
◦ Thermal Cycling
◦ Impact Resistance
◦ Reliability (SIR)

Technical Considerations for Wave Soldering Fluxes Designed for Lead-free Assembly
• Ability to be evenly applicable by spray, wave, or foam applications
• Activator package able to sustain higher preheating temperatures
• Able to be used with a variety of lead-free finishes, bare copper OSP, gold nickel, tin, silver immersion, tin-copper
• Sustained activity, the flux should remain active throughout the contact time with the molten solder, insuring good peel back of the solder
• Low dross potential, the flux must not react excessively with the molten solder as to create large amounts of dross
• The flux must not discolor or char at the higher soldering temperatures associated with lead-free wave soldering
• The flux should not decompose at the higher solder temperatures
• The flux residues must be benign if it is a no-clean flux, and easily washed in hot water if it is a water washable flux type

Technical Considerations for Lead-free Cored Solder Wires
•The flux should not spatter or fume excessively at the slightly higher soldering temperatures associated with lead-free soldering
•The flux should have activator systems designed to solder a variety of lead-free board and component finishes
•The flux must be active enough and remain active enough during tip contact to compensate for the reduced wetting of lead-free alloys
•The flux residues must be benign if it is a no-clean type, or easily removed in hot water if it is a water washable type cored solder
•The residue should not char or darken in color when using slightly higher solder tip temperatures

Source: Kester Solder Co.

How do you prepare a solder pot for lead-free solder?

Tuesday, August 18th, 2015

How do you ready a solder pot for lead-free solder?
It is important to first insure the solder is lead-free solder compatible. High tin alloys tend to leach iron causing dissolution of iron and solder contamination. The dissolution can advance to the point of causing micro-cracks and thinning of the walls, eventually resulting in a solder spill.

Materials that are lead-free solder compatible are:
• Titanium
• Cast iron
• Ceramic coatings
• Melonite coatings
• Specialty coatings, unique to the equipment maker

If a pot is lead-free compatible but contains leaded solder it can be cleaned before lead free solder is added. Cleaning is very important to avoid the introduction of lead. The limit required as per RoHS Directive is only 0.1%. Most lead-free solders will contain a small amount of lead in the range of 0.05%; there is little room for unintentional contamination.

A standard procedure for wave machine cleaning is detailed below:
1.Empty the pot completely
2. Drain any remain solder
3. After cooling use a scraper to gently remove any visible leaded solder
Avoid damage to the metal finish during scrap down
4.Clean ducts, baffles and impeller mechanism thoroughly
5. Clean conveyor chain and fingers with a steel brush, removing all lead-bearing solder particulates.
6. Fill machine with pure tin to clean any remaining leaded solder
7. Run system at 500º F for 2 hours, circulating the solder
8. Empty completely, removing all visible excesses
9. Refill with lead-free solder
10. Do an analysis for lead and iron after running pot for one hour

For dip pots and selective soldering pots, the cleaning is simpler but complete removal
of leaded solder is required and a tin fill is a less demanding process since the volume is
substantially less. A pot analysis for lead and iron is still required.
Note: If a tin wash is not performed it becomes imperative to remove all traces of leaded
solder in all parts of the solder pot area. The risk is highly increased in reference
to lead contamination. Tin washing is therefore preferred
About the author:

Source: Peter Biocca, Senior Market Development Engineer with Kester Inc.

Lead-Free Hand Soldering

Tuesday, August 18th, 2015

Lead-free Hand-soldering – Ending the Nightmares

Most issues during the transition seem to be with Hand-soldering

As companies transition over to lead-free assembly a certain amount of hand-soldering will always be there. An article from Tech Search International last year did say that in Asia where lead-free is highly used, hand-soldering was more of a problem than lead free SMT or wave soldering. Kester has been getting numerous calls in reference to hand-soldering with lead- free in recent months. In fact most problem calls and requests for training through Kester University are related to lead-free hand-soldering and rework. In many cases the assemblers are using materials from various solder suppliers with similar issues occurring in all cases. Often the problems are more than material issues.

Switching to lead-free on Monday morning when Friday operators were soldering with leaded solder is not recommended. Although this seems easily understood some assemblers have attempted this, with line stoppages occurring only a few hours into lead-free hand-soldering. Operator complaints, loss of reliability and poor joint quality were experienced. This could be a production engineer’s nightmare but it need not be this way if the basic concepts of hand-soldering are revisited, some experience gained prior to the transition and adequate training of operators is performed before and after the switchover.

Here are some questions often asked by assemblers in reference to hand-soldering with lead-free solders. These are in fact also some of the issues addressed during the lead free hand-soldering on-site audit done through Kester University.

Which alloys and fluxes are compatible with lead-free hand-soldering?
The limiting factor with lead-free solders is probably its availability in wire form; some alloys are not easily drawn into wire, as is the case with tin-bismuth solders. At this time the most popular alloys used to make wire are tin-silver-copper and tin copper based solders. This compliments the industry well at this time where 68% of SMT assemblers and 50% of wave assemblers have chosen tin-silver-copper (SAC) solders. In wave soldering 20% have chosen tin-copper (SnCu) based solders due to the cost of lead-free solder bar. Wire solders for hand-assembly are therefore readily available in these two alloys.

The main differences between SAC and SnCu solders are the melting points; the melting temperatures are approximately 217ºC and 227ºC respectively. From a soldering performance perspective, SAC wets more readily than SnCu based solders, so flow with SAC solders, everything else being equivalent, will be better. Both SAC and SnCu solders are available in no-clean, water washable and rosin based flux formulas. No-clean accounts for over 85% of the total wire usage while water washable is less than 15% and rosin based fewer than 5%. These numbers apply to
North America. In other parts of the world no-clean is dominant.

What are the key variables in choosing a good lead-free solder wire?
By far the flux content in the wire will be a critical factor in determining wetting behavior.
Lead-free solders such as SAC, SnCu and the higher temperature option tin-antimony SnSb wet a little slower than 63/37 when compared using similar conditions in wetting balance tests.

Lead-free solder wires should contain at least 2% flux by weight. Leaded solders are available with lower flux percentages as low as 1% wt/wt; this low flux volume will not work well with lead-free.
Typical flux distribution in a solder wire, the density of the flux is close to 1 g/cc; therefore the volume is
more obvious in the cross-section. Multiple cores are used at times but the percent is usually 2 or 3 %
for lead-free. Less flux results in more difficulties during soldering.

If wetting is still too sluggish 3% flux in the wire may be tried but this will give higher residues, not always cosmetically appealing in no-clean applications. The addition of flux using a squeeze bottle is normally not acceptable due to over application issues. This is not acceptable for no-clean applications. Another important point is to insure the flux is designed for lead-free applications and therefore it should be able to withstand higher soldering tip temperatures without charring, spattering and decomposition. Some fluxes may smoke more when using hotter tip temperatures.

When choosing a solder wire make sure to observe the flux IPC classification. Many no-cleans meet the ROL0 classification meaning they are rosin based, low activity and halide free. These are the most reliable and meet the SIR and corrosiveness tests in the IPC specification. With lead-free there is a tendency to use higher activity to compensate for the reduced wetting; this is not always a good idea. Water washable fluxes will be more active classed often as ORH1 and do better with lead-free soldering. However insure the residues are still completely removable in hot water; doing ionic contamination testing is recommended. If ionic contaminants still
remain after water washing, a clean process change may be warranted such as increasing the cycle time, water temperature or a change of the cleaning agent. In comparative studies done with SAC and SnCu wetting balance tests indicate that using the same flux types that SAC out-performs SnCu solders in the time required to reach maximum wetting. This applies also to SnCu solders with dopants of nickel, cobalt or other additives. In choosing an alloy it is important to determine the overall solderability of the parts to be assembled. If the parts are older, more oxidized, manually handled SAC solder may be a better choice.

What are the main changes associated with lead-free hand assembly cosmetics?
Lead-free solders flow a little slower than 63/37 using the same activation levels for the fluxes. The contact angles are slightly larger and feathering out of the solder is therefore less pronounced. The solder joints tend to be less reflective than 63/37 solder. Some retraining is required prior to a full transition to lead-free is done. In some cases certain shrinkage effects as described in Section 5 of the IPC-STD-610D occur. The IPC-610 classifies these as soldering anomalies and not necessarily defects. As mentioned on page 5-22 of the above document, it is not a defect for Class 1, 2 and 3 if the tear bottom is visible and the shrink hole does not contact the lead, land or barrel wall. See the photos below for examples taken from the Kester laboratory.

What is the best soldering tip temperature for lead-free SAC and SnCu?
The temperature of the tip or contact temperature is very important to ease the lead-free hand-soldering operation. When using 63/37 solders temperatures as low as 650ºF have been used but with lead-free 700-800ºF is best. The higher temperature does compensate for the slower wetting exhibited with these lead-free alloys. Above 800ºF issues of board and component damage may arise; at lower temperatures cold solder joints and flagging are the normal complaints. Higher temperatures and longer contacts with the parts to be soldered may also increase the intermetallic bond layer. So avoiding prolonged contact and repeated rework is not recommended. The above diagram shows what happens as the bond layer increases in thickness a higher risk of embrittlement occurs. The risk of de-wetting also increases with higher temperatures.

How about the soldering tips with lead-free solders?
Lead-free tips are required however just as important is the choice of tip design. Lead free is less forgiving and the right tip for the job will go a long way in prevent defects. Chose a tip with enough heat delivering capacity. Fine point tips cannot be used in all applications and in some cases a tip such as a chisel type is best suited to deliver sufficient heat to the parts to be soldered.

How about tip life with lead-free solders?
Tip life will be reduced with lead-free solders and it is important to choose tips really
designed for lead-free soldering. Many tips are only tinned with lead-free solder and the iron plating is no different than traditional soldering tips. High tin solders like to dissolve iron and this reduces tip life. Some assemblers have reported important reductions in tip-life for example a manufacturer reported that with 63/37 the tips lasted 3 months with lead-free the tip-life was only 3 weeks. Not all soldering tips are equal when comparing dissolution rates so choosing tips carefully and asking for more compatibility information is a good practice. Lead-free tip failure after 3 weeks Cross-section of typical solder tip, with lead-free the solder is lead-free

How can a good lead-free hand-soldering process be had, which will ease the lead-free soldering operation?
In a recent study, which appeared in the Lead-free Update by Tech Search International in December 2004, hand-soldering was found to be more problematic to implement when compared to lead-free wave soldering and SMT.
The reason could be that hand-soldering is more operator dependant than reflow and wave soldering but also the surface tension in lead-free solders is slightly higher.

Wetting or spread is also a little slower when compared to 63/37.
To reduce operator issues and reduced wetting proper optimization of the soldering process is key. To avoid issues use a flux content of 2-3% by weight in the solder wire, use a solder tip temperature of 700-800º F. Also Tin-Silver-Copper (SAC) solder will flow more readily than Tin-Copper (SnCu) solder.

The main issues encountered with lead-free hand-soldering are cold solder joints, poor wetting, flagging and de-wetting. These can be avoided.

A step-by step process transition would be as follows:
Insure the tips are designed for lead-free
Insure the temperature is set to 700-800 ºF
Insure the flux content in the wire is a least 2% wt/wt
Use LF tips with the longest life
Use the correct tip for the job
Insure the parts are easily solderable with the chosen flux
Avoid prolonged contact times
Avoid needless reworking of the joint
Avoid the use of additional liquid flux
Which defects or issues can appear and how can they be avoided?
The common issues reported with lead-free are:
Grainy joints
Cold solder joints
De-wetting
Flagging
Poor wetting and wicking
Flux charring and darkened residues
Difficulty with the cleaning of residues
Grainy joints can be due to too high a tip temperature and the dissolution of the metals
to be joined.

Cold solder joints can be due to several things such as too low a tip temperature, too weak a flux or insufficient flux in the wire. De-wetting can be caused by prolonged tip contact and the dissolution of the plated
metals, exposing a less solderable surface. Too high temperatures can also cause this. Flagging can be caused with the use of too high soldering tip temperatures or the use of solder wires with low volumes of flux. Flux activity may be low also and prolonged contact with the iron is de-activating it.

Flux charring with no-cleans and cleaning difficulties especially where water washable is used can be due to soldering temperatures being to high or the flux is not properly designed for the higher temperatures required for lead-free. Avoiding prolonged contact and using lower soldering temperatures can help with this situation.
My soldering iron tips are charring, turning black and de-wetting when I use lead free solder wire, what can I do?

Not all fluxes are created equal and some are thermally incapable of sustaining the higher soldering temperatures used with lead-free solder. A recent video clip from OK International demonstrates this well when two solder wires are compared side by side and this is called the “black tip syndrome”. Less thermally stable resins turn the tip black and makes re-tinning more difficult also. Once “black tip syndrome” occurs the reduction in heat transfer makes lead-free hand soldering difficult, tip life is reduced, tip costs and operator frustration goes up and
reliability goes down.

Proper flux selection, using lead-free tips and lead-free hand solder process training for
operators will offset these costs.

The important points to help avoid these problems are listed below.
Use lead-free solder wires with lead-free designed fluxes
Avoid using too high temperatures
If tip tinner is used, wipe excess tinning material on a clean sponge
Do not use pressure to compensate for lack of wetting
Use the right tip geometry
Use the correct wire diameters
Segregate work areas for lead-free and leaded
Identify lead-free irons and work stations
Train all operators on the expectations

These are some of the questions asked by customers moving forward with lead-free assembly. A little training goes a long way in avoiding costly issues with the hand soldering process.
Although the process is more operator dependent using the tech tips mentioned above can make hand-soldering less frustrating for the operators and engineers. Maintaining the same levels of reliability they are accustomed to with leaded soldering is therefore very achievable with no nightmares of poor joints or reduced production output. .

Source: Peter Biocca is Senior Market Development Engineer with the Kester Co. He is a chemist with 24 years experience in soldering technologies.

Soldering Tip Maintenance

Tuesday, August 18th, 2015

Soldering Tip Maintenance: Tip Tinners
Proper soldering iron tip maintenance is important to extend the life of iron tips. Keep the tips tinned by frequently melting a small length of rosin core solder directly on the tip and then wiping off the excess with a damp (not wet) sponge. The Tip Tinners are small containers of solder in powder form with a special tinning flux. Wipe the hot soldering iron tip on the surface of the tip tinner, melting some of the solder on the tip. Wipe off any excess on a damp sponge. Source: Kester Solder Co.