Archive for the ‘Soldering Supplies’ Category

Syringable Paste Needle Size

Tuesday, August 18th, 2015

Syringable solder paste requires a needle and plunger for application. The 100 g paste comes in a standard 30cc. syringe. 35 g samples come in a standard 10 cc syringe. Most distributors carry plungers and needles. Scientific supply companies such as Fisher Scientific (www.fishersci.com) and Cole Parmer (www.coleparmer.com) also carry plungers and needles. For dispensing SMT solder paste a 20 gauge needle is the smallest that is usable.

Organic Acid (Water-Soluble) Solder Paste

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. Source: Kester Solder Co.

No Clean Solder Paste. What is it?

Tuesday, August 18th, 2015

Method of determining the deposition rate of spray fluxers

Tuesday, August 18th, 2015

Procedure

1. Take a sheet of transparency film for copy machines.
2. Roll up the film and put a rubber band around it.
3. Weigh the paper on an analytical balance. Weigh to the nearest 0.0001 grams.
4. Unroll the film and affix it to the bottom of a board using paper clips.
5. Run the board through the fluxer and remove to dry.
6. After drying (15-30 min.) look at the paper. Look for anomalies in the spray pattern.
7. Reweigh the paper and rubber band (1,000,000 micrograms per gram).
8. Calculate the weight of flux in micrograms per in2 (remember to subtract the weight of the
paper and rubber band).
Wt of flux in micrograms = X micrograms/in2
Paper is 88 in2
9. Minimum value is 700 micrograms/in2
10. Recommended value is 1000 micrograms/in2

How much no-clan flux should be applied to a pcb and how does one determine the deposition?

Tuesday, August 18th, 2015

Procedure

1. Take a sheet of transparency film for copy machines.
2. Roll up the film and put a rubber band around it.
3. Weigh the paper on an analytical balance. Weigh to the nearest 0.0001 grams.
4. Unroll the film and affix it to the bottom of a board using paper clips.
5. Run the board through the fluxer and remove to dry.
6. After drying (15-30 min.) look at the paper. Look for anomalies in the spray pattern.
7. Reweigh the paper and rubber band (1,000,000 micrograms per gram).
8. Calculate the weight of flux in micrograms per in2 (remember to subtract the weight of the
paper and rubber band).
Wt of flux in micrograms = X micrograms/in2
Paper is 88 in2
9. Minimum value is 700 micrograms/in2
10. Recommended value is 1000 micrograms/in2

Kester VOC-Free Wave Soldering Profile Chart

Tuesday, August 18th, 2015

kester-voc-free-wave-soldering-profile-chart

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

Solder Flux Test Kits

Tuesday, August 18th, 2015

Kester Flux Test Kit
The Kester PS-20 and PS-22 test kits are used for flux control of low residue(no-clean) fluxes. The PS-20 and PS-22 test kits are acid titration kits. As solvent evaporates, the acids in the flux become more and more concentrated. The kit is used to determine the acid number of the flux. The test is a simple drop test with an indicator for the endpoint (similar to a swimming pool test). You count the drops and then go to a chart. From the chart you determine how much thinner to add to bring the acid number back down to spec. Traditionally flux control is maintained by measuring the density of the flux and adding thinner as the flux thickens. This is a good method for fluxes with high solids contents. A slight change in density corresponds to a small change in the flux. The no-clean fluxes have low solids percents (typically 2 or 3 %) so a small change in the flux density could reflect the change in solids of 25-30%. This would put the acid level unacceptably high. The test kits are more accurate than using density measurements as a way to monitor the flux.

What Does No-Clean Mean?

Tuesday, August 18th, 2015

What Does No-Clean Mean?
There is some apprehension at the description, ‘no-clean’. What does it mean? The flux category called “no-clean” . Many fluxes fall into this category because the flux residues are not harmful to assemblies. It does not mean there will be no residues. All fluxes leave residues (the solids are the active portion of the flux that does all the work). Some flux residues are conductive or corrosive and must be removed. Other fluxes like the no-clean fluxes leave residues that do not need to be removed.

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.