Electronics Assembly Knowledge, Vision & Wisdom
Results with Benchtop PCB Cleaning
Results with Benchtop PCB Cleaning
This paper examines the role variables play in aerosol cleaning and offers guidelines to improve an aerosol cleaning process.
Production Floor

Production Floor programs cover topics including:
CAD/CAM/CIM/EDA, Circuit Board Handling, Clean Room, Cleaning Operations, Component Insertion, Component Prep, Dispensing, Feeders, Fume Extraction, Hand Tools, Labeling/Marking, Lasers, Material Handling, Odd Form, Ovens/Curing, Packaging, Stencil Printing, Repair/Rework, Soldering and more.
Submit A Comment
Comments are reviewed prior to posting. You must include your full name to have your comments posted. We will not post your email address.

Your Name


Your Company


Your E-mail


Your Country


Your Comment



Authored By:
Lindsey Shehan, Chemist
Techspray, Amarillo, Texas USA

Transcript
The purpose of this study was to determine whether or not aerosol benchtop cleaning can consistently and reliably clean reworked boards.

Different variables that play a role in the effectiveness of aerosol benchtop cleaning were examined.

These variables include straw attachment, spray technique, spray angle, handheld cleaning tools, brush attachments, and a final rinse.

While no approach to aerosol benchtop cleaning was found to be 100% effective all of the time, the study did yield good information that can be used as general guidelines to improve benchtop cleaning processes.

So what were the conclusions.

There is no - one size fits all - approach to aerosol benchtop cleaning.

There are too many variables involved in benchtop cleaning that prevent developing a method or formula for cleaning that appears per visual inspection to be 100% effective.

That being said, some methods do work better than others, and selecting the correct combination and formalizing the process will reduce variability.

The following information is intended to be used as a general guide to improve benchtop cleaning effectiveness.

1. First, boards should be held in an upright position for cleaning, at a slightly backward angle, approximately 30 degrees was used in testing.

2. As the board is cleaned, keep the board in this same upright position, do not rotate the board. This board position helps to ensure that all residues move in the same direction throughout the entire cleaning process, down, and eventually off of the board.

3. Using an aerosol with a straw attachment helps to focus the solvent spray; thus, eliminating excessive waste.

4. A pre-rinse should be used; wetting the entire area to be cleaned from top to bottom. This step begins solvating the flux residues.

5. The next focus should be on the corners of each of the components to be cleaned. A short burst under each corner, down into top corners and up into bottom corners, will help to break up any flux dams located there.

It is important that this step comes early in the cleaning process, as clearing the corners of the components of flux residue opens the number of paths the solvent can travel as it works its way under the component. When spraying corners, work from top to bottom.

6. Attention should be given to each side of the contaminated components by spraying back and forth across each side of the component. To keep all residues moving in the same direction, down and off, work your way around the components moving from top to bottom.

For each side, keep the straw angled so that it is spraying under the component. This step is an opportunity to remove flux residues from under the components. It is better to slightly overdo this step. If you underestimate and don't use enough solvent here, you will only move the residues around, not out from under the component.

7. Spray each component surface, angling the straw to spray away from each side of the component. This helps to move residues away from the component and ensure that no residues are trapped between the leads.

8. The last step is the final rinse. Again, working from top to bottom spray the affected area to rinse all residues completely off of the board.

Summary
The purpose of this study is to determine whether or not aerosol benchtop cleaning can consistently and reliably clean reworked boards. Different variables that play a role in the effectiveness of aerosol benchtop cleaning were examined. These variables include straw attachment, spray technique, spray angle, handheld cleaning tools, brush attachments, and a final rinse.

While no approach to aerosol benchtop cleaning was found to be 100% effective all of the time, the study did yield good information that can be used as general guidelines to improve benchtop cleaning processes.

Conclusions
There is no "one size fits all" approach to aerosol benchtop cleaning. There are too many variables involved in benchtop cleaning that prevent developing a method/formula for cleaning that appears to be (per visual inspection) 100% effective all of the time. That being said, some methods do work better than others, and selecting the correct combination and formalizing the process will reduce variability.

Initially Published in the IPC Proceedings

Comments
No comments have been submitted to date.
Free Newsletter Subscription
Every issue of the Circuit Insight email newsletter will bring you the latest information on the issues affecting you and your company.

Insert Your Email Address

Directory Search


Program Search
Related Programs
bullet Cleaning R.F. Circuits - Aqueous or Vapor?
bullet Evaluating Rinsing Effectiveness in Spray-In-Air Cleaners
bullet PCBA Cleaning with Sodium Bicarbonate
bullet Delay Before Cleaning Partial Assemblies
bullet pH neutral Cleaning Agents - Market Expectation & Field Performance
bullet Effect of SMT Component Package Design on Cleaning Effectiveness
bullet Results with Benchtop PCB Cleaning
bullet Video Analysis of Solder Paste Release from Stencil Printing
bullet Seeking Alternatives to Solvent Cleaning
bullet Incoming Circuit Boards - How Clean Is Clean?
More Related Programs