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IMPROVING YOUR WAVE SOLDERING

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PEM Technologies BRINGING TECHNOLOGY TO THE INDUSTRY IMPROVING YOUR WAVE SOLDERING Igmar Grewar Technical Director PEM Technologies Wave Soldering Conveyor PCB ... – PowerPoint PPT presentation

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Title: IMPROVING YOUR WAVE SOLDERING


1
IMPROVING YOUR WAVE SOLDERING
PEM Technologies BRINGING TECHNOLOGY TO THE
INDUSTRY
  • Igmar Grewar
  • Technical Director
  • PEM Technologies

2
Wave Soldering
  • Conveyor
  • PCB transported over the wave

3
The 6 Basic Steps of Wave/Selective Soldering
  • Component preparation
  • Insert components
  • Apply Flux
  • Preheat PCB
  • Soldering
  • Cool down

4
Preforming THT components
  • Cost saving
  • Higher production output
  • Quality

5
The effect of hole sizes
  • Hole size less than 1.5 times lead thickness
    bend of slightly less than 90º
  • A dimple is formed on the lead for hole size more
    than 1.5 times lead thickness
  • Raised from PCB to allow for cleaning or heat
    dissipation

6
Selective Pallets
  • Stable support platform for PCB
  • Eliminate masking by hand
  • Eliminate glue dotting for SMDs
  • Reduce solder defects such as skips and bridging
  • Pockets and channels promotes solder flow
  • Standardize conveyor width reduce setup time
  • Multiple PCBs on a pallet higher throughput

7
The Wave Soldering Process
Picture courtesy of Cobar/Balver Zinn
8
Fluxing
  • Why do we need flux?
  • Prevents oxidation
  • Acts as a wetting agent

Picture courtesy of Cobar/Balver Zinn
9
Fluxing Wave Solder
  • Two common types of fluxing methods
  • in wave soldering
  • Foam fluxing
    Spray fluxing

Pictures courtesy of Seho
10
Foam fluxing Wave Solder
  • Flux control required
  • Ideal contact area 20mm
  • Ideal flux stone pore size 3um - 10um
  • Air pressure 2 - 3bar
  • Raise or lower the whole flux station to achieve
    the right contact
  • Never use a foam fluxer without an air knife
  • Not suitable for water based fluxes

Picture courtesy of Seho
11
Flux Control (foam fluxer)
  • Critical parameters
  • Flux density (solid content)
  • Water content
  • Temperature
  • Contamination from PCB or compressed air
  • Replace flux in foam fluxers completely every 40
    hours
  • Cleaning of foam pipe

12
Spray fluxing - Wave Solder
  • Single side PCB requires 100 Micro Gram per Cm2
    of PCB surface (Check Flux Data Sheet)
  • PTH PCBs will require 20 more
  • Check the spray pattern by wrapping a piece of
    photo sensitive fax paper around a bare PCB and
    let it run through the fluxer
  • Combination of airflow, flux flow, moving speed,
    distance of nozzle to PCB
  • Paper must be evenly gray from flux, not wet and
    certainly not dripping

Picture courtesy of Seho
13
Advantages of Spray fluxing
  • Quantifiable application of the flux deposit
    (SPC)
  • No in-process QC of the flux
  • No thinner consumption
  • Direct application from can
  • Reduced flux consumption
  • No flux drippings over the preheat zone

Picture courtesy of Seho
14
Conversion to Spray flux
  • The Plug n Spray spray-fluxer
  • Stand alone fluxer

Picture courtesy of Cobar/Balver Zinn
Picture courtesy of Seho
15
Incorrect Flux Volume
  • Too little flux can cause soldering defects such
    as bridging and skips
  • Excessive flux can lead to solder balling and
    unwanted and uncured residue left on the PCB

Picture courtesy of Bob Willis
Picture courtesy of Cobar/Balver Zinn
16
Flux Classification - IPC-J-STD-004
17
Flux Types
  • Alcohol based (100 VOC)
  • Long history of reliability process know how
  • Modest in preheat requirements
  • Can be applied by spray or foam
  • High residue safety and wide process window
  • Hazardous flammable material
  • Contributing to the "green-house" effect

18
Flux Types
  • Low-VOC (40 water / 60 alcohol)
  • Modest in preheat requirements
  • Safer to the environment
  • Can be applied by spray or foam
  • High residue safety and wide process window

19
Flux Types
  • Water based (100 VOC-free)
  • More soldering power
  • Environmentally safe
  • Non-flammable
  • Requires more preheat
  • Spray fluxing only
  • Some process adjustments required
  • Risk for corrosion if flux is not properly
    polymerized by the heat of the wave (flux under
    pallets, on topside or just too much flux
    applied)

20
Preheat
Functions of Preheating
  • Evaporation of the solvent in the flux
  • Activating the flux
  • Minimizing the Delta T between the PCB and the
    solder wave

Picture courtesy of Cobar/Balver Zinn
21
Preheat
  • Types of Preheating

Infra Red elements
Quartz elements
Forced Convection
Pictures courtesy of Seho
22
The Preheat Profile
Picture courtesy of Cobar/Balver Zinn
  • Preheat temperature is measured on the top side
    of the PCB
  • Typical max. preheat temperature Sn/Pb 90ºC -
    120ºC
  • Typical max. preheat temperature Pb-Free 100ºC
    - 130ºC

23
Measuring Preheat Temperature
Temperature Profiler / Thermocouples
Adhesive Temperature Strips
Infrared Thermometer
Picture courtesy of TWS Automation
Picture courtesy of www.tempstrips.com
24
Measuring Preheat Temperature
25
Incorrect Preheat
Picture courtesy of Cobar/Balver Zinn
  • Preheat too high or too long may break down the
    flux activation system and cause shorts / icicles
  • Preheat too low may cause problems such as skips
    or unwanted residues left on the PCB

26
Soldering Phase
  • Wetting Phase
  • Wicking Phase
  • Drain Phase

PCB ------ gtgt
Wave
Draining
Wicking
Wetting
Picture courtesy of Cobar/Balver Zinn
27
Soldering Phase
  • Nominal angle 7º
  • Contact Width 20 to 40mm wide for Delta Wave
  • Contact Width 15mm wide for Chip Wave
  • Dwell time Tin/Lead 3.5 sec _at_ 235ºC solder pot
    temperature
  • Dwell time Tin/Lead 2.5 sec _at_ 250ºC solder pot
    temperature
  • Dwell time Pb-Free 2 to 5 seconds _at_ 260-270ºC
    solder pot temperature, depending on the
    application
  • Conveyor speed 0.8 1.5 m/min
  • Conveyor speed (m/min) Contact width (cm) x
    Dwell time (sec)
  • Wave height 1/3 2/3 of PCB thickness
  • High temperature glass plate is used to measure
    contact width and parallelism to the wave

28
Wave Nozzle Configuration
  • Delta Nozzle
  • Standard Nozzle for through hole components
  • Fast moving solder moving in the opposite
    direction of PCB for wetting action
  • Small volume of solder moving along with the PCB
    for wicking action

Picture courtesy of Seho
Picture courtesy of Bob Willis
29
Wave Nozzle Configuration
  • Chip Nozzle
  • Turbulent wave
  • Can be added in addition to the Delta Nozzle
  • High Kinetic Energy
  • Avoids shadowing

Picture courtesy of Seho
Picture courtesy of Bob Willis
30
Wave Nozzle Configuration
  • Dual Wave
  • Turbulent chip wave combined with a slow moving
    horizontal wave overcomes the limitations of
    other wave types
  • Solution for overcoming the shadow effect on SMT
    components not aligned to the wave

Picture courtesy of Seho
Picture courtesy of Seho
Picture courtesy of Bob Willis
31
Wave Nozzle Configuration
  • Other Nozzles
  • For components requiring high wave pressure or
    high flow dynamics
  • For PCBs with high thermal mass
  • To optimize contact time

Pictures courtesy of Seho
32
Solder Alloy
  • Lead Containing Alloy Sn/Pb
  • Contains Tin / Lead
  • Sn63/Pb37
  • Melting point of 183ºC
  • Solder pot temperatures from 235 - 250ºC
  • Eutectic alloy melts and solidifies at the same
    temperature
  • Low surface tension good wetting
  • Low viscosity great hole fill and top side
    fillet forming

33
Solder Alloy
  • 4 Popular choices for Lead-Free
  • SAC (Tin/Silver/Copper)
  • SAC X (Tin/Silver/Copper X)
  • SnCu (Tin/Copper)
  • SnCuNi (Tin / Copper / Nickel)
  • Your choice of alloy will be dependant on your
  • specific requirements

34
Solder Alloy
  • SAC
  • Tin / Silver / Copper
  • Typical Sn96.5/Ag3.0/Cu0.5
  • Melting point of 217 - 221ºC
  • Solder pot temperature 260ºC
  • High silver content
  • Solder joints looks different than Tin-Lead
  • Dull joints due to shrinkage

35
Solder Alloy
  • SAC X
  • Tin / Silver / Copper X
  • X Co, Fe, Bi, Si, Ti, Cr, Mn, Ni, Ge, and Zn
  • Typical Sn98.3 Ag0.3 Cu0.7Bi0.7
  • Melting point of 216 - 225ºC
  • Solder pot temperature 265ºC
  • Lower material costs vs higher silver SAC alloys
  • Performance and appearance similar to higher
    silver SAC alloys

36
Solder Alloy
  • SnCu
  • Tin / Copper
  • Sn99.3/Cu0.7
  • Melting point of 227ºC (Eutectic alloy)
  • No silver content - lowers alloy cost
  • Lower tendency to leach copper - less loss of
    conductive copper in tracks and pads
  • Poor fluidity at typical lead free temperatures
  • Poor through-hole filling and forming of solder
    bridges between components

37
Solder Alloy
  • SnCuNi
  • Tin / Copper / Nickel
  • Sn99.25/Cu0.7/Ni0.05
  • Melting point of 227ºC
  • Eutectic alloy free of shrinkage
  • Solder pot temperatures from 265ºC
  • Does not contain silver - running costs are low
  • Small addition of nickel in to the SnCu alloy
    improves fluidity
  • Good fluidity less bridges and better hole
    filling
  • Dross rate equal or lower than tin-lead solder
  • Lower aggressiveness towards stainless steel
  • Bright smooth solder joints

38
Solder Bath Analysis
  • For Tin-Lead, every 3 to 6 months
  • For Lead-Free, every 4 6 weeks after initial
    fill during the first 6 months, thereafter every
    3 to 6 months is recommended

39
Transition to Lead Free Alloys
  • Higher preheat temperatures required
  • Corrosion of metal parts

Pictures courtesy of Seho
40
Solutions for Lead-Free
  • Pause the PCB in the preheater
  • Coated parts available, pumps, solder nozzles and
    solder pot

Pictures courtesy of Seho
41
Cooling Phase
Picture courtesy of Cobar/Balver Zinn
  • Forced cooling or not?
  • No improvement in joint quality
  • To speed up production

42
Nitrogen or Not?
  • Displaces oxygen
  • Reduced dross formation
  • Increase surface tension
  • Improved flow of solder
  • Better wetting

Pictures courtesy of Seho
43
Most common causes of problems
Skips Bridges Insufficient Hole Fill Solder Balls Blowholes
Component leads too long X
Insufficient flux X X X
Excessive flux X X
Flux density too low X X X X
Flux density too high X X X
Moisture trapped in PCB X X
Preheat temperature too low X X X X X
Preheat temperature too high X X X X
Conveyor speed too low
Conveyor speed too high X X X X X
Conveyor angle too small X X
Solder temperature too low X X X X
Solder temperature too high X
Solder is contaminated X X
Uneven or erratic solder wave X X X X
Solder wave height too low X X
Solder wave height too high X X
Solder mask properties X X
Poor solderability of the PCB or component X X X
44
Thank you for your AttentionAny Questions?
www.smartgroupsa.org
PEM Technologies BRINGING TECHNOLOGY TO THE
INDUSTRY
www.pemtech.co.za
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