|
Static electricity is often the cause of problems encountered in the bindery, hampering production and affecting product quality. By having a basic
understanding of static electricity and by utilizing ionization equipment to
control or eliminate the static charges, most common problems can be
tackled.
What Causes
Static Electricity?
Static electricity is an
electrical charge on the surface of an insulative material such as film or
paper. Static also can occur on a conductor, such as metal, if it is not
grounded.
When two or more surfaces are
in contact with each other, a transfer of electrons takes place between
those surfaces. When the surfaces separate, the surface which has gained the
electrons becomes negatively charged. The mating surface giving up the
electrons becomes positive. The contact and separation is known as
triboelectrification or tribocharging.
There are several factors that
effect whether or not a material’s surface will support a static charge and
to what degree.
Materials made of natural
fibers, such as uncoated paper, typically exhibit high charges at high
speeds in environments having low relative humidity. These materials tend to
be very hygroscopic, having the ability to absorb moisture from the ambient
air. As moisture collects on the surface of these materials, surface
resistivity decreases which, in turn, increases its conductivity. This
provides a conductive path along the surface for charges to flow to grounded
metal rollers or any grounded metal surface in the machinery that the
material may be in contact with, thus removing the charge from the print
material.
Materials such as plastic
films and paper with plastic coatings or high quality clay coatings tend to
generate high charges even at slower machine speeds. Their high propensity
for charging is due to the inherent high surface resistivity of materials
with less tendency to absorb moisture. Some of these surfaces can support
static charge potentials of tens of thousands of volts and maintain a charge
for minutes, hours, or even several days. For that reason feeding, delivery,
and stacking plastic or lightweight coated paper sheets can be a real
challenge.
Some plastics may have been
treated with an antistatic agent which can reduce the tendency to develop a
charge. Plastic webs or sheets may be extruded with an antistat in the
formulations. Many times papers are treated in the printing press with an
application of fabric softener solution which acts as an antistat on the
material. In either case, the antistat functions as a slip agent, reducing
friction by attracting ambient moisture to the surface and increasing
conductivity.
Other factors affecting charge
generation are material speed, contact pressure, temperature, and type of
surfaces in contact. Typically, high speeds result in higher static charges.
Larger areas of surface contact and greater physical pressure prior to
separation also result in higher charges.
Surfaces that are conductive
or antistatic can be maintained in an electrically neutral condition by
grounding. Materials such as plastics, resin coated and clay coated papers,
and very dry uncoated papers are non-conductive. Grounding cannot eliminate
static charges on their surface. Static charges on these materials can be
controlled, however, by utilizing ionization equipment mounted in the
process machinery.
Familiar to most machine
operators, static bars are a common type of ionizer used for neutralizing
sheets and webs. A typical static bar is electrically powered and is mounted
in the production line an inch or two from the sheet or web material’s path.
As the charged surface passes the static bar, it becomes neutralized.
Placement of the ionizer is critical. It should be placed just ahead of the
area in the process where static is causing the problem. It is recommended
that a qualified static field specialist be consulted for proper ionizer
selection and placement. This can save a lot of time and aggravation.
How Does an
Ionizer Work?
Ionizers emit vast quantities
of both negatively and positively charged gas molecules called air ions. The
ions are made available to the charged surfaces where the electric field
attracts the necessary ions of opposite polarity to its surface, thus
balancing the charge on the web. The ionizer’s output is virtually
unaffected by ambient temperature and relative humidity conditions and is
compatible with most materials processed in the bindery.
A typical static bar has a
range of about one to two inches. Some static bars are designed to operate
up to several inches away from the target surface. Ionizing blowers consist
of a fan blowing air over a series of ionizing emitters to extend the
operating range even more, up to three to four feet. Ionizing nozzles and
air knives use compressed air to provide a higher velocity of focused
ionized air. A common application is to assist in sheet separation on pocket
feeders.
Dealing
with Static Problems During Production
Many of the problems relating
to static electricity encountered in the bindery actually result from static
charges generated in the print medium in the pressroom. As the web or sheet
is transported through the various stages of the printing press, static
charges accumulate on the surfaces. If static neutralizers are not used at
the delivery of the press, a highly charged stack of printed materials is
sent to the bindery. If the print media in a quality clay or resin coated
material has large areas of ink coverage or is highly calendered, the static
charges may be retained for several hours or even days if ambient conditions
permit. The resulting problems encountered in the bindery are usually
personnel shocks, jams in the press, or double-sheet pick-ups when trying to
feed a subsequent operation such as a folder, collator, saddle stitcher, or
perfect bound line.
The simple and most cost
effective solution to these problems is to convince the pressroom to install
a static neutralizing bar at the delivery of the press. Trying to deal with
the problems of double-sheet pick-ups and jams at all the pocket feeders on
a large side saddle stitcher or perfect binder can be complicated due to
limited space and moving mechanisms at the pocket. A static-free stack of
printed materials from the pressroom, however, doesn’t solve all the bindery
problems. For example, with a typical sheet folder, once the sheet leaves
the feed pile, the tribocharging process starts all over again as the sheet
contacts and separates from belt, rollers, and any other surfaces with which
it comes into contact. Since tribocharging is a cumulative process, the
charge on the sheet continues to rise to a level where the charged sheet is
attracted to components of the machine and a jam or skewing of the sheet
occurs. When making multiple folds, this can happen at several locations in
the folder. A solution is to mount a static neutralizing bar over the paper
path, just ahead of the point where the problem is occurring. Due to guides
and rails which may interfere with placing a standard static bar an inch or
two from the sheet, an extended range type static bar may be appropriate.
For best results, the bar should be positioned where the sheet is floating
with a little air space between it and the sheet machine bed. One ideal
location, although not always possible, is to position the bar over the
sheet at a transition point or break in the conveyor.
Folded materials obviously
need to be delivered onto a stack. This is usually where the next problem is
manifested. The folded pieces may repel each other, causing a mess at the
delivery, or they may stick to each other, resulting in sloppy, uneven,
impossible-to-jog stacks. In either case, two static bars properly placed at
the delivery to neutralize both outer surfaces of the folded piece will
render neat, trouble-free deliveries.
Personnel
Shock
Uncomfortable electrical
shocks to personnel in the bindery are not uncommon. When high static
charges exist, especially in rolls or stacks of materials, the electric
fields can induce a charge into nearby personnel. Since the human body is a
conductor and usually insolated from ground due to rubber or synthetic soled
shoes, a sizable charge can build up and will be stored in the body. When
the charged person touches something conductive, such as a machine component
or control panel, the discharge will be felt as an electrical shock. Using a
static fieldmeter, or with the help of a qualified static control
specialist, the cause of the electrical field can be located and the problem
solved by neutralizing the source of the problem.
Shrink Wrap
Packaging Problems
As a roll of film unwinds and
passes through nip rolls, over idler rolls, turning bars, and the forming
plows, static charges on the film can cause operator shock, press jams due
to film clinging to itself or machine components, and breakage of the film.
The attraction forces of the charged film may even lift non-adhesive labels
off the item being wrapped. A couple of carefully placed static bars usually
solve all these problems and result in trouble-free packaging operations.
Summary
Electrostatic charges develop
on the print substrate during virtually all phases of printing and
finishing. The resulting problems can slow production and affect the quality
of the end product, both impacting the bottom line.
With the help of an
experienced static control field representative and the proper placement of
an appropriate static control device, static charges can be controlled in
production machinery, enhancing product quality and increasing throughput in
the finishing department.
Scott
Shelton is the North American Sales Manager for SIMCO Industrial Static
Control, an international manufacturer of static control products. During
his 28 years at SIMCO, he has authored and coauthored several published
technical articles and has presented technical sessions to the Society of
Manufacturing Engineers, Society of Plastics Engineers, Screen Printing
Association, U.S. Department of Energy, OSU Web Handling Research Center,
Pressure Sensitive Tape Council, TAPPI, IML CON, and various electronics
industry and industrial manufacturing groups. |
