There
always seems to be a mystery about parts cleaning applications. It's really quite
simple to understand the basics, but there is much art and science beyond the
surface. No article, especially one as short as this one, can make you a cleaning
expert. But you can acquire enough understanding to approach an application intelligently
and to guide you through the selection process.
There are four factors
that affect the cleaning process: chemistry; temperature; mechanical energy; and
time. The factors are generally synergistic. For example, in most cases adding
a little heat (temperature) makes the cleaning solution (chemistry) more effective.
Consider a cleaning job
that virtually all of us have done at least once, washing the dishes following
a breakfast including eggs sunny-side up. Generally, there is some chemistry involved
in the cleaning process, typically a detergent. Most of us know from experience
that trying to clean dirty dishes without a detergent is difficult. We've all
learned that the dishes are easier to clean with warm water. Usually it becomes
a matter of how much heat your hands can stand. Even with a hot detergent solution
it is necessary to scrub at least a little. The harder you scrub, the better the
process works. The final factor is time. If you soak the dishes for a while, less
scrubbing (mechanical energy) is required.
Chemistry
Most chemistries used in aqueous cleaning fit into one of three categories according
to pH.
Neutral cleaners, the mildest
of cleaners, are preferred when soils are light. Generally they are environmentally
friendly. Depending on local codes and the composition of the soils that become
part of the mix during use, spent cleaning solutions can sometimes be disposed
of without further treatment.
Alkaline cleaners are the
most commonly used cleaners for removing oils, greases and general soils. There
are numerous chemistries available depending on the type and degree of contamination,
the material to be cleaned, the type of cleaning equipment used and the subsequent
use of the cleaned material.
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| Five tank
automated ultrasonic cleaning system
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Acidic cleaners are primarily
used to remove tarnish and oxides and to brighten non-ferrous metals. Although
some limited cleaning of organic soils (such as oils) is possible with some acidic
chemistries, they are rarely used for general cleaning. It is not unusual, however,
to use an acidic chemistry to brighten work previously processed with an alkaline
cleaner and a rinse.
Temperature
Temperature has a significant effect on cleaning efficiency in most applications.
Generally, the hotter the cleaning solution is, the faster cleaning occurs. One
application that illustrates the effect of temperature is the removal of buffing
compound. Most buffing compound formulations contain a significant portion of
fats. Try to remove it at 120F and you are in for a long day. At about 150F cleaning
becomes possible. At 180F cleaning is much easier. This is because the higher
temperature softens, or pre-conditions, the contamination and allows the chemistry
to work more efficiently.
There are other considerations
concerning temperature. In a buffing compound removal application with brass parts,
using 180F could cause the parts to tarnish as soon as they are removed from the
cleaning solution. For this application there is more than one right answer. You
can back off on the temperature and accept a longer cleaning cycle. Alternately,
you can add another wash step (and rinse) using an acidic chemistry to remove
the tarnish. This trade-off is typical of many cleaning applications where the
advantages and disadvantages of various alternatives need to be balanced.
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| Cabinet
spray washer
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Mechanical
Energy
Mechanical energy is sometimes described in more technical articles as "impingement"
which refers to the application of mechanical force. Going back to the breakfast
dishes, it is easy to visualize the more common forms of mechanical energy in
relation to washing the dishes.
Mechanical scrubbing is
the most common method of applying mechanical energy when washing the dishes by
hand. The energy is usually delivered using a cloth or a sponge. In industrial
cleaning, mechanical scrubbing is not common. Probably the greatest single reason
for not using mechanical scrubbing in industrial applications is the maintenance
required. For example, a simple rotating brush will wear and require constant
adjustment to achieve consistent cleaning. The brush will also require periodic
replacement.
A simple method of applying
mechanical energy is to move the dish through the cleaning solution. Do it for
a while, and the dish becomes clean. In industrial applications there are several
types of equipment that operate on the principle of part agitation. The most common
type of part agitation machine uses vertical agitation. The repeated up and down
motion is effective in cleaning simple parts, such as parts without blind holes
and/or deep grooves. Another type of part agitation machine uses a rotating basket,
typically for small parts that tumble through the cleaning solution as the basket
rotates. There is also part on part contact with a rotating basket that adds some
mechanical scrubbing into the process.
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| Miniature
conveyor type spray washer
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Instead of moving the dish
through the cleaning solution, the cleaning solution can be moved over the dish.
Okay, so its not really a practical way of washing dishes by hand, but it illustrates
the point. For industrial parts cleaning, there is practical equipment that uses
liquid agitation. Methods for moving the liquid include impellers, eductors and
air agitators. Liquid agitation can also be an effective way of cleaning simple
parts without blind holes and deep grooves. It's not unusual to add liquid agitation
to other types of equipment to increase effectiveness. For example, it is not
unusual to combine a rotating basket with liquid agitation.
Most homes today have a
dishwasher. It produces the mechanical energy for cleaning the dishes by spraying
them with cleaning solution at some velocity. There are similar industrial spray-wash
cleaning machines known as cabinet washers. They differ from the household variety
in several ways. They are generally of higher capacity; the spray is usually of
higher pressure (velocity); the spray nozzles are fixed; and the parts move on
a turntable. Spray washers that move the parts in-line by conveyor are also common
in industrial applications. The parts are moved through the wash, rinse and dry
stages of the machine.
In reviewing the previous
forms of applying mechanical energy to parts cleaning, comparing the process to
washing dishes makes an obvious and intuitive connection. This is not so with
ultrasonic cleaning. Therefore, an explanation of how ultrasonic cleaning works
is necessary.
Ultrasonic cleaning depends
on a phenomenon called "cavitation."
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| Bench top
ultrasonic tank
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In ultrasonic cleaning,
a sound wave is created in water in a manner similar to the way an audio speaker
creates sound in air, by vibrating a diaphragm. As the sound wave passes through
the water, alternating areas of high and low pressure are created. As the frequency
of the sound becomes higher, the sound waves are closer together. When the frequency
approaches the limit of human hearing and beyond, the alternating high- and low-pressure
areas occur fast enough that cavitation can occur on a microscopic scale if the
intensity (amplitude) of the sound wave is high enough.
The mechanical energy in
ultrasonic cleaning occurs when the cavitation bubble implodes (collapses rapidly).
Water rushes in to fill the space formerly occupied by the vapor bubble, at high
velocity, although not exactly evenly. The result is "micro-jetting"
that provides the mechanical energy for cleaning.
Cavitation occurs everywhere
throughout the liquid, including deep grooves and blind holes, everywhere that
the liquid can reach. Ultrasonic cleaning is effective on parts that are not cleanable
by other methods.
A quick note about ultrasonic cleaning and chemistry is needed here. Not all cleaning
chemistries are suitable for use in ultrasonic cleaning equipment. For good cavitation,
the cleaning solution should have high surface tension, low vapor pressure and
low viscosity. Consultation with your chemical supplier and/or equipment supplier
is recommended.
Time
The fourth factor, time, is an important consideration in cleaning applications.
For a given set of process conditions, longer exposure generally results in cleaner
parts.
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| Parts washer
with rotating basket combines part agitation, mechanical scrubbing and liquid
agitation.
|
Going back to the breakfast
dishes as an example, consider this scenario. You're running late one morning,
and you just gather up the dishes with all of that runny egg residue and leave
them in the sink. For cleaning them later that evening you might want to consider
using a hammer and chisel. However, if you fill the sink with a warm detergent
solution and come back in a couple of hours, you should have an easy job. In industry,
production and economic requirements almost always influence the cleaning time
that is available.
No discussion of aqueous
cleaning is complete without mention of the importance of adequate rinsing. Depending
on the material being cleaned, the chemistries used, and the cleanliness specifications,
anything from a simple immersion or spray rinse to multiple rinses, including
an ultrasonic rinse, may be required. Rinsing can be especially important with
parts made from more than one metal. Chemical residue between the different metals
can act like a battery and promote long-term corrosion.
Before beginning to develop
a cleaning process, it's best that you are able to answer an often-overlooked
question: How clean is clean? The answer can vary widely. For example, a machined
aluminum bracket for a farm tractor accessory may need to be only clean enough
for the assembler to handle and attach it without making a mess. On the other
hand, an aluminum valve body for an ABS brake system may need to be 100% free
of any particles greater than 10 microns.
The objective of this article
is to provide a general understanding of aqueous cleaning and the factors that
contribute to a successful application. Hopefully it has been at least partially
successful. There is much more art and science involved that can and has filled
complete books on the subject. Even those of us who are involved daily never stop
learning.
