Wave soldering is a bulk soldering process used for the manufacturing of printed circuit boards. The circuit board is passed over a pan of molten solder in which a pump produces an upwelling of solder that looks like a standing wave. As the circuit board makes contact with this wave, the components become soldered to the board. Wave soldering is used for both through-hole printed circuit assemblies, and surface mount. In the latter case, the components are glued onto the surface of a printed circuit board (PCB) by placement equipment, before being run through the molten solder wave. Wave soldering is mainly used in soldering of through hole components.

Inside a wave soldering machine, showing the wave soldering process
Temperature and time graph showing wave soldering solder pot and topside temperatures

As through-hole components have been largely replaced by surface mount components, wave soldering has been supplanted by reflow soldering methods in many large-scale electronics applications. However, there is still significant wave soldering where surface-mount technology (SMT) is not suitable (e.g., large power devices and high pin count connectors), or where simple through-hole technology prevails (certain major appliances).

Wave solder process

edit
 
A simple wave soldering machine.

There are many types of wave solder machines; however, the basic components and principles of these machines are the same. The basic equipment used during the process is a conveyor that moves the PCB through the different zones, a pan of solder used in the soldering process, a pump that produces the actual wave, the sprayer for the flux and the preheating pad. The solder is usually a mixture of metals. A typical leaded solder is composed of 50% tin, 49.5% lead, and 0.5% antimony.[1] The Restriction of Hazardous Substances Directive (RoHS) has led to an ongoing transition away from 'traditional' leaded solder in modern manufacturing in favor of lead-free alternatives. Both tin-silver-copper and tin-copper-nickel alloys are commonly used, with one common alloy (SN100C) being 99.25% tin, 0.7% copper, 0.05% nickel and <0.01% germanium.[2]

 
Wave solder optimizer fixture example showing sensors

Fluxing

edit

Flux in the wave soldering process has a primary and a secondary objective. The primary objective is to clean the components that are to be soldered, principally any oxide layers that may have formed.[3] There are two types of flux, corrosive and noncorrosive. Noncorrosive flux requires precleaning and is used when low acidity is required. Corrosive flux is quick and requires little precleaning, but has a higher acidity.[4]

Preheating

edit

Preheating helps to accelerate the soldering process and to prevent thermal shock.[5]

Cleaning

edit

Some types of flux, called "no-clean" fluxes, do not require cleaning; their residues are benign after the soldering process.[6] Typically no-clean fluxes are especially sensitive to process conditions, which may make them undesirable in some applications.[6] Other kinds of flux, however, require a cleaning stage, in which the PCB is washed with solvents and/or deionized water to remove flux residue.

Finish and quality

edit

Quality depends on proper temperatures when heating and on properly treated surfaces.

Defect Possible causes Effects
Cracks Mechanical Stress Loss of Conductivity
Cavities Contaminated surface

Lack of flux
Insufficient preheating

Reduction in strength

Poor conductivity

Wrong solder thickness Wrong solder temperature

Wrong conveyor speed

Susceptible to stress

Too thin for current load
Undesired bridging between paths

Poor Conductor Contaminated solder Product Failures

Solder types

edit

Different combinations of tin, lead and other metals are used to create solder. The combinations used depend on the desired properties. The most popular combinations are SAC (Tin(Sn)/Silver(Ag)/Copper(Cu)) alloys for lead-free processes and Sn63Pb37 (Sn63A) which is a eutectic alloy consisting of 63% tin and 37% lead. This latter combination is strong, has a low melting range, and melts and sets quickly (i.e., no 'plastic' range between the solid and molten states like the older 60% tin / 40% lead alloy). Higher tin compositions give the solder higher corrosion resistances, but raise the melting point. Another common composition is 11% tin, 37% lead, 42% bismuth, and 10% cadmium. This combination has a low melting point and is useful for soldering components that are sensitive to heat. Environmental and performance requirements also factor into alloy selection. Common restrictions include restrictions on lead (Pb) when RoHS compliance is required and restrictions on pure tin (Sn) when long term reliability is a concern.[7][8]

Effects of cooling rate

edit

It is important that the PCBs be allowed to cool at a reasonable rate. If they are cooled too fast, then the PCB can become warped and the solder can be compromised. On the other hand, if the PCB is allowed to cool too slowly, then the PCB can become brittle and some components may be damaged by heat. The PCB should be cooled by either a fine water spray or air cooled to decrease the amount of damage to the board.[9]

Thermal profiling

edit

Thermal profiling is the act of measuring several points on a circuit board to determine the thermal excursion it takes through the soldering process. In the electronics manufacturing industry, SPC (Statistical Process Control) helps determine if the process is in control, measured against the reflow parameters defined by the soldering technologies and component requirements.[10] Products like the Solderstar WaveShuttle and the Optiminer have been developed special fixtures which are passed through the process and can measure the temperature profile, along with contact times, wave parallelism and wave heights. These fixture combined with analysis software allows the production engineer to establish and then control the wave solder process.[11]

 
An example fixture used for capturing process data from the wave soldering machine

Solder wave height

edit

The height of the solder wave is a key parameter that needs to be evaluated when setting up the wave solder process.[12] The contact time between the solder wave and assembly being soldered is typically set to between 2 and 4 seconds. This contact time is controlled by two parameters on the machine, conveyor speed and wave height, changes to either of these parameters will result in a change in contact time. The wave height is typically controlled by increasing or decreasing the pump speed on the machine. Changes can be evaluated and checked using a tempered glass plate, if more detailed recording are required fixture are available which digitally record the contact times, height and speed. Also, some wave solder machines can give the operator a choice between a smooth laminar wave or a slightly higher-pressure 'dancer' wave.

 
Contact times and shape of wave solder on underside of PCB

See also

edit

References

edit
  1. ^ Robert H. Todd; Dell K. Allen; Leo Alting (1994). Manufacturing Processes Reference Guide. p. 393. ISBN 978-0-8311-3049-7.
  2. ^ "SN100C Solder" (PDF). aimsolder.com.
  3. ^ "Archived copy" (PDF). www.ipctraining.org. Archived from the original (PDF) on 14 March 2014. Retrieved 13 January 2022.{{cite web}}: CS1 maint: archived copy as title (link)
  4. ^ Todd p. 396
  5. ^ Michael Pecht (1993). Soldering Processes and Equipment. p. 56. ISBN 978-0-471-59167-2.
  6. ^ a b Giles Humpston; David M. Jacobson (2004). Principles of Soldering. p. 118. ISBN 978-1-61503-170-2.
  7. ^ Todd p. 395
  8. ^ "THE QUICK POCKET REFERENCE FOR TIN/LEAD AND LEAD-FREE SOLDER ASSEMBLY" (PDF). aimsolder.com.
  9. ^ Todd, Robert H.; Allen, Dell K.(1994). Manufacturing Processes Reference Guide. New York: Industrial Press Inc.
  10. ^ "IPC-7530 Guidelines for Temperature Profiling for Mass Soldering Processes (Reflow & Wave)" (PDF). ipc.org.
  11. ^ "Wave Solder Optimizer". www.solderstar.com.
  12. ^ "Importance of Wave Height Measurement in Wave Solder Process Control" (PDF). solderstar.com.

Further reading

edit