Our thanks to Conformity Magazine Published in December 2004 issue
http://conformity.com/artman/publish/feature_207.shtml
Accurate process evaluation provides real answers
Provided by the ESD Association by Stephen Halperin, in collaboration
with Ron Gibson
“We need to spend HOW MUCH?”
Recently, a company experienced several large losses due to electrostatic
discharge (ESD) and had a very unhappy customer on their hands. The
manufacturing vice president now faced a substantial expenditure for new ESD
loss prevention equipment. The company’s first step had been to hire an ESD
consultant who recommended the purchase of several thousands of dollars in
ionization equipment and monitoring instruments for several of the company’s
facilities.
The troubled VP read the report several times looking for justification
of the expense. However, the report did not define how the recommended equipment
would meet the VP’s specific needs. Other than describing how ionization reduced
electrostatic charge after it is generated and that the instruments could
confirm that a discharge occurred, the report did not identify the actual cause
of the process problem. No ESD measurements were described. There were no
details related to cause of product loss, device sensitivity concerns, value
issues, process and handling details, examination and description of existing
controls, or rationale for how the recommended tools would solve the problem in
question. The report was clearly based on the consultant observing the process
of a single manufacturing environment. In effect, the report made a purchasing
recommendation based on a “blanket” opinion, not on facts specific to the needs
of the company or their customer. Such an approach typically makes a bad
situation worse. While the recommended tools may have been very useful for
investigating a process or for solving defined problems, they are expensive Band
Aids“ when used in undefined problem situations.
Today’s electronic manufacturing environment demands that minimal ESD
controls be in place to provide fundamental protection for electrostatic
discharge sensitive (ESDS) devices. When basic ESD controls are employed and
losses still occur, manufacturing and quality managers face more difficult
problems., In assessing the problem, companies struggle with a variety of major
questions concerning a specialized technology, while having minimal information
and available skills. To avoid the risk of making the wrong investment decision
without solving the initial problem, management needs a way to select and
implement the most effective ESD controls that fit their financial situation,
solve their specific problems, and provide a respectable return on their
investment.
Why bother with ESD; what’s the big deal?
ESD control, other than a dramatic increase in sales, is the single most
profitable opportunity for industry under today’s economic conditions.1
Independent consultants have found that ESD costs the average electronic
manufacturer 4 to 8 percent of total annual corporate revenues, depending on
product designs and device sensitivity.1 Internal studies in telecommunication
and other electronic firms have revealed losses equal to, or in excess of, 10
percent of annual revenues.1 At an estimated average impact of 6.5 percent of
revenues, this means the international electronics industry is losing in excess
of $84 billion (USD) every year based on production data from 1997 through
2001.1
When faced with this information, a manager might exclaim, “This can’t be
possible. If we lost this much money we’d be out of business.” That would be
true if these losses were in addition to current operational costs and
profitability. Unfortunately, all of these ESD related losses are included in
current operational budgets. Electronics industries are losing literally tens of
billions of dollars each year due to ESD, and most organizations plan for these
losses, allow them to occur, and budget for them. Therefore, effective ESD
controls can make a significant impact on profits.
Seeking Balance: ESD Control Costs Versus
Benefits
How can we avoid the problems our VP was facing when addressing ESD
controls and program development? How can we identify our specific problems and
develop the best ESD control program for the lowest cost and maximum return on
investment? Let’s explore these issues in greater detail.
All of us share the same objective: achieve effective ESD control that
eliminates or minimizes damage and product loss while enhancing quality,
productivity, and profitability. If we meet the objective in a manner suitable
to our products and process, our returns are typically far greater than the cost
of implementation. In a well-designed and balanced ESD program, history tells us
that within the first year we can expect a minimum of five dollars in return for
each dollar invested in ESD controls. Often returns are hundreds and even
thousands of times the original outlay. But, how does one actually achieve this
objective and generate a return on the investment? The following steps are an
effective beginning for meeting these goals:
1. Understand the specific manufacturing process thoroughly
2. Hire or train personnel who understand the process and have ESD
expertise
3. Select and implement ESD controls that meet the specific needs of the
process and the devices being handled.
Understand the process. Even the most difficult ESD-related
problems are fairly basic and can be resolved using a classic analytical
approach—first define the cause of the problem then identify a suitable
solution. A thorough assessment of the manufacturing process critical path,
procedures, control materials, and environmental factors will either identify
the cause of specific ESD problems and indicate suitable controls, or confirm
that a problem does not exist. The keys to effective ESD analysis involve
understanding the manufacturing process and products, knowing ESD analysis
techniques, having an insight into the company’s or customer’s needs, and
knowing the variables that affect them. Unfortunately, most organizations do not
have ready access to experienced ESD technologists who have a clear
understanding of all these elements.
As part of the evaluation, one must remember that every situation,
facility, process, and work force is different. Some products are expensive and
may be used in critical, sometimes life threatening or saving situations. Other
products are low cost or have little critical impact to the user. Everyone’s
problems are different, and the consequences of these problems span a huge
spectrum of application impact.
Assessing the Process: An Illustration
There is a significant difference between simply installing ESD controls
and hoping for the best and evaluating an environment for what is needed prior
to specifying product purchases and installation. For example, consider a person
generating body voltage by walking or moving within the environment. If that
excessive body voltage is discharged to a sensitive device, there is a chance
that the damage threshold of the device will be exceeded, possibly resulting in
catastrophic ESD damage or partial degradation (latent damage) to that
device.
Before recommending a variety of ESD prevention controls, an ESD
specialist would determine the probability of personnel damaging a sensitive
device during handling and transport. A series of measurements in the facility
using readily available instruments and standard test methods (e.g., ESD STM
97.2-1999, ESD STM 97.1-1999, ESD STM 7.1-2001, etc.) would answer several
questions.
Once these fundamental measurements were completed, a variety of
calculations would be performed and the results would be compared to the Human
Body Model (HBM) damage threshold of the most sensitive device in the process.
This assessment would address the following concerns:
1. What is the probable range of body voltage generation during transport
of sensitive devices through the process?
2. What is the probable range of body voltage generation while working at
an assembly machine or standing at workstation and handling sensitive
devices?
3. What is the probability of equaling or exceeding any given HBM damage
threshold during handling and transport?
4. Is there an actual or potential problem when handling or transporting
these devices in this process?
5. What is the most effective means of handling and transporting
sensitive assemblies in the existing environment without ESD damage?
6. What process modifications would enhance ESD protection and expedite
the flow of products through the environment?
7. Which modifications, if any, would be financially most
beneficial?
Depending on the product value, criticality, and other operational
requirements this assessment would help determine if ESD controls are necessary
and to what degree. If an ESD problem does exist a return on investment can be
calculated. A similar assessment, albeit more complex, can be performed on
automated assembly and processing equipment.
Those individuals who perform the process analysis and select the ESD
controls must have a clear understanding of the manufacturing and ESD universe.
The ESD programs they design should be in harmony with process needs; they must
select ESD controls that are adequate, but not too profuse or demanding for the
operation in question. The selection and mix of ESD controls and procedures
should be well balanced for the operation’s requirements. Next, let’s look at
the people who should perform the process evaluation.
1. Hire or train personnel who understand the process. So, what is one of
the most effective ways to solve a variety of ESD problems and do so profitably?
Start by using trained ESD practitioners to assess your process and maintain
your ESD control program. There are three sources for obtaining trained
personnel to assess and maintain your facilities.
2. Train selected company employees. A current employee who is familiar
with the process can be trained as an ESD program manager. This may require
additional education such as the ESD Association national and regional tutorials
and professional certification educational programs. There are also experienced
ESD consultants who conduct private seminars, in house training, and public
seminars.
3. Hire ESD practitioners trained by other organizations. Many
corporations have made substantial efforts to develop in-house ESD expertise.
During the past few years, personnel cuts have resulted in many of these
individuals being laid off, or retiring. Many have either moved to other
organizations or are looking for new situations.
4. Use contract services provided by professional static control (ESD)
service firms. While several are available to service your needs, seek those who
are experienced and well qualified. Many ESD consulting firms have websites, and
a basic “search” will locate several for your consideration. Most professional
ESD advisors are members of the ESD Association. While membership does not
necessarily guarantee results or technical knowledge, it does indicate an
interest in the ESD industry and its technical and standard developments.
Regardless of where you find qualified expertise, the successful ESD
practitioner has a fundamental background and knowledge in identifying and
solving ESD problems. Furthermore, when it comes to establishing a certifiable
ESD control program, e.g., ANSI/ESD S20.20, an effective ESD advisor has clear
and objective understanding of the client’s actual control needs, rather than a
“packaged” approach for controlling only those elements that are important to
the advisor.
Having consulted in the ESD field since the late 1970s, and having
trained many ESD practitioners, we find that successful ESD specialists have
skills, knowledge, and experience in common. For example:
1. They have worked in technical environments and have process experience
in the manufacturing of complex products or materials.
2. They have a sound understanding of ESD theory and associated
measurements.
3. They can relate the theory to ESD sensitive processes and environments
in a manner that clarifies the problem’s cause and process needs.
4. They can transform the client’s specific needs into a tailored ESD
program.
5. They are capable of performing an in-depth assessment of a process,
and have a full understanding of the risks and ESD problems before making a
recommendation for control.
Select and implement ESD controls. The next step is to select the
right controls from a variety of available ESD products, materials, devices, and
“tools.” The “right” controls for the large manufacturer of expensive medical
life support equipment may be far more extensive than those used by the small
manufacturer of low cost consumer products. Interestingly, they must both meet
the same objectives, but they may do so in different ways, with differing levels
of redundancy.
Effective ESD control requires that the process interaction between
people, equipment, materials and devices:
1. Generate static charge at a level that does not exceed the damage
threshold of the most sensitive device in the process;
2. Readily dissipate generated charges to ground and maintain all devices
and process elements at the same potential;
3. Use protective packaging when sensitive items are stored in, or
transported through uncontrolled areas.
These requirements can be met by adhering to the three fundamental
principles for developing an ESD control program in accordance with ANSI/ESD
S20.20:
1. Ground/bond all conductors.
2. Control charges on all non-conductors.
3. Use protective packaging for transit and storage.
A basic set of ESD controls may consist simply of (1) a static controlled
worksurface, (2) an operator wearing a wrist strap connected to a common ground
point with the controlled worksurface, and (3) a static controlled protective
bag. This combination of controls is considered a basic electrostatic protected
area, or EPA. Assuming that all assembly, testing, or repair events are
conducted at this EPA, the product will be protected within the EPA.
Expanding Basic ESD Controls To Meet Specific Process and
Productivity Needs: Another Example
Most process environments are more complex than a single workstation and
may require additional controls beyond the basics. For example, if many
controlled workstations are necessary to perform the entire manufacturing or
product assembly, each workstation must be an EPA. If the floor is not static
controlled, the devices must be transported between controlled workstations
(EPAs) in a closed ESD protective bag, package, or tote box. This is necessary
because the person transporting the products from one EPA to the next is
generating a charge while walking across an uncontrolled floor.
In large, active facilities it may be far more efficient to install an
ESD floor and provide ESD control footwear to all manufacturing employees. In
this way the employee is either grounded as though wearing a wrist strap, or
cannot generate a harmful charge during the transport process, or both. This
eliminates the need for enclosing sensitive devices in protective containers and
allows greater employee mobility.
To assess the benefit of expanded ESD controls, ask questions pertinent
to your situation, such as:
1. Will an ESD-controlled floor and footwear combination increase
employee productivity while reducing potential damage during in-plant transport?
If greater mobility and less internal packaging enhance process profitability,
using these controls makes a great deal of sense.
2. Will an ESD-controlled floor and footwear combination provide added
protection for high value, critical products? If redundant controls minimize or
eliminate damage, reduce related warranty and customer service costs on high
value products, using these controls may be of significant value.
3. Will an ESD-controlled floor and footwear combination provide
sufficient “passive” control such that our devices are protected regardless of
the employee’s action during transport? If the work force has high turnover or
includes a large percentage of temporary workers, redundant passive controls can
offset the lack of experience.
4. Will an ESD-controlled floor and footwear combination provide obvious
ESD awareness sufficient to remind employees and customers of management’s
commitment to ESD control? If the facility services many major customers that
have ESD control guidelines governing the manufacture of their products, obvious
ESD controls are a desirable sales and service feature. The required use of
controlled footwear in a sensitive environment is a constant reminder to all
employees that ESD protection is essential.
Similar consideration would apply to other key ESD control elements,
including:
1. Floors
2. Worksurfaces
3. Equipment (Chairs, Carts, and Production Equipment)
4. Personnel Grounding
5. Clothing
6. Raw Materials
7. Production Aids (Tapes, Solvents, tools, fixtures, etc.)
8. Packaging
9. Grounding
But what should we buy?
Certainly, there are other ESD tools available such as auditing
instruments, ionization, monitoring systems, and training. However, all of these
ESD control products should be viewed simply as “tools,” much like those in a
carpenter’s tool chest. Some tools are required, some are used only under
occasional, specific circumstances, and others are “nice to have” when you need
them. Clearly, it is best to use the proper tool for a given job to provide the
desired results, and do so under the most advantageous financial conditions.
Once we determine that an ESD tool is necessary to solve a specific
problem, the next question is what should we buy? To answer this question, the
application and its parameters need to be defined, and the required attributes
established. Among the concerns to be considered are:
1. Application Description: Where is the product being used, why,
and how? What’s good about the present product, what’s unacceptable? A product
used in a hot, humid environment may have different desired attributes than one
being used in a cold, dry area. What is the desired life of the product, or is
it disposable?
2. Mechanical Requirements: What’s physically necessary to do the job
properly? With floors, we consider type and density of traffic and possibly
appearance; for packaging, we consider size, strength, and shock. When assessing
worksurfaces, we would select hard, smooth surfaces for assembling system
chassis, and soft, cushioning materials for small mechanically sensitive
items.
3. Chemical Concerns: Are there factors to consider, such as corrosion,
contact contamination, outgassing, flammability, or other material compatibility
issues? If so, what are they and how would you quantify them?
4. Electrostatic Performance Requirements:
a. In our process, how much charge would be generated? What’s too much
for our application?
b. How does the charge move from the material to ground? What do we need
in this application?
c. How quickly does the measure employed, whether a material, or possibly
an ionizer, dissipate the charge?
d. If a package, is shielding required, and if so, what kind and to what
degree?
e. Are there special processes or requirements for the application,
within the company or for the customer?
5. Safety: Use of the product or material should be safe for personnel,
while end of life disposal is a concern to the environment.
6. Value: When assessing the value of a product, we are primarily
concerned with meeting the process and operational requirements outlined above
in terms of suitability for the application, meeting mechanical, chemical, and
electrical requirements, while being safe for employees and the environment.
In our example, if ESD floors and footwear are good control points for
the process and solve HBM device failures, then one must make the above
assessment as to which floor and footwear system is most suitable for the
operation. Ultimately, one may be faced with the decision as to whether one
selects a permanent floor or uses high performance ESD polish, and whether heel
straps or ESD shoes should be selected. Note that ESD floors and footwear work
together to achieve optimal body voltage control.
The flooring decision may be based on how long the operation will be in
the facility and comparative costs. For example, the cost of ESD floor polish
and maintenance labor tends to equal the cost of an installed floor at
approximately the 2-1/2 to 3 year point. If you plan to move or re-model within
that period, floor polish may be more cost effective short term than installing
a permanent floor. Heel strap use and performance are very inconsistent, while
ESD shoes provide exceptional performance and user reliability at a defined
cost. Contractors and visitors are great candidates for using heel straps, as
they do not typically handle work in process; all others should wear ESD shoes.
This is the most effective ESD control combination at the lowest
cost.
Certainly, there are many variables for choosing ESD control products,
but such decisions are part of the process assessment. All of these
considerations relate directly to the organization’s performance and
productivity needs. The approach applies to solving many ESD
problems.
Smart Managers Make Money With ESD Controls
Obviously, when one is experiencing ESD problems they must be solved in
an expeditious manner. The same is true when complying with customer
requirements, or simply trying to prevent ESD loss in a highly sensitive
environment. Without a doubt, the highest ESD cost is customer dissatisfaction
due to unsatisfactory product quality and reliability. The essence of effective
static control is to eliminate these problems through accurate assessment of the
process, and choosing the most effective and suitable ESD controls.
However, smart management understands that the costs of operation include
losses due to a variety of non-productive elements. ESD is one of these costs
that are built into the budget in terms of material inventories, rework and
labor, field service and warranty costs. If these budgeted ESD related costs are
reduced by 80 percent, the average organization can add approximately 5 percent
profit to their bottom line without increasing sales. That’s why ESD controls
are one of the most profitable means of enhancing product reliability and
productivity in today’s market place. ¦
References
1. Stephen A. Halperin, “ESD control: profitable opportunity in tight
economic times,” Threshold, January/February 2003, copyright ESD
Association.
About The Authors
Stephen Halperin is the founder of Stephen Halperin & Associates,
Limited, and Prostat Corporation. Halperin has over 30 years experience
controlling the effects of electrostatic discharge in complex applications in
industrial environments. He is known for his work in facility and process
evaluation and static control techniques for highly sensitive environments.
Halperin is a charter member of the ESD Association and has served several terms
as an elected member of the ESDA Board of Directors, two years as senior vice
president, two years as president, and is currently advisor to the Executive
Committee as past-president of the ESD Association. Halperin can be reached at
Stephen Halperin & Associates, 1072 Tower Lane, Bensenville, IL 06016,
630-238-8883, email: shalperin@halperinassoc.com.
Ron Gibson is the corporate ESD program manager for Celestica
International, Inc., based in Toronto, Canada. Gibson has been a member of the
ESD Association since 1988 and has been active in various standards development
committees. He has served as vice president, senior vice president and president
of the ESD Association. Gibson is currently the chairman of the ESD Association
Standards Committee and chairman of the ESD Association Certification Program.
Gibson can be reached at Celestica International, Inc., Department 349, MS 34,
844 Don Mills Road, North York, Ontario M3C 1V7 Canada, 416-448-5524, email: rgibson@celestica.com.
About The ESD Association
Founded in 1982, the ESD Association is a not for profit, professional
organization dedicated to furthering the technology and understanding of
electrostatic discharge. The Association sponsors educational programs, develops
ESD standards, holds an annual technical symposium, and fosters the exchange of
technical information among its members and others. Additional information may
be obtained by contacting the ESD Association, 7900 Turin Rd., Bldg. 3, Rome, NY
13440-2069 USA. Phone: 315-339-6937. Fax: 315-339-6793. Email: info@esda.org. Website: http://www.esda.org/.
*Reproduced with Permission,
Conformity
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