B
Ben Dellar
Many computer users perform their own hardware upgrades, and a
distressing number of these result in insufficient damage to the
system. Destroying your own computer is every user's right and is
the pattern of behaviour expected by the manufacturers and,
especially, repair personnel, whose very livelihood is put in peril
by those users who perversely persist in correctly upgrading their
This article will explain to you, the user, the most common ways by
which you can cause your computer to cease to function. Follow the
instructions carefully and you will shortly find yourself making
appropriate contributions to the all-important service sector.
First, it is essential to be incorrectly prepared.
When opening the case of your computer, you will probably be
presented with a number of hexagonal head Phillips-slotted screws.
These can be easily removed with a Phillips screwdriver or 6mm nut
driver, but using a flathead screwdriver, especially one that is
slightly too big, maximises the chance of the screwdriver slipping
from the screw head and smashing into one or another of the
computer's connectors. Personal injury is also possible, especially
if excessive force is used when turning a screw the wrong way, but
the object is to damage the computer, not yourself.
If any components of your computer are held in place with Pozidriv
screws (superficially similar to Phillips head screws, but
recognisable by the cross scored on the screw-head at 45 degrees to
the slots), use of a Phillips head driver instead of the squarer
tipped Pozidriv gives the maximum chance of reaming out the screw
head and, with luck, damaging the driver as well.
When removing screws from the back of an ordinary clone case, ensure
that you extract every screw in sight, not just the ones around the
edge that actually hold the case on. This will, with any luck, cause
the computer's power supply to fall off inside the case and cause
serious damage, before you even have to take off the lid.
Leaving one fastening screw still done up in the corner and then
attempting to wrench off the case may cause significant damage to
the metalwork, but this is generally easily bent back into shape and
not very expensive to replace. You can do better.
Fortunately, there are a plethora of computer case designs, and a
gratifying number are fiendishly difficult to take apart and,
especially, reassemble. To maximise the chance of damage, ignore any
locking tabs and slots, don't worry about pinching cables in the
case, and make sure you push really hard.
When replacing screws, remember to tighten everything as if the
computer were a major structural component of the Sydney Harbour
Bridge. Overtightening screws increases the chance of reaming the
heads, and the extra frustration involved in removing super-tight
screws increases the chance that someone will give up and turn the
machine over to a professional. Use of an electric screwdriver makes
screw destruction easy for anyone.
Use of computer cases as furniture is an excellent way to obey your
entropic imperatives. Many PC cases are in fact very strong, and so
it's necessary to balance large monitors, tabletops, grand pianos
and twelve foot fireproof safes upon them to ensure rapid
destruction. Fortunately, the pop-riveted construction of most cases
and their poor endurance under lateral loads means that even
relatively small stresses can, over time, cause sufficient
structural creep to snap a solidly attached motherboard. Patience,
and not buying enough chairs, can be a virtue.
Static Is Your Friend
It is possible to destroy computer components just by touching them,
thanks to electrostatic discharge (ESD). Static electricity
accumulates best on humans when the air is dry and both the carpet
and the soles of the shoes are made of synthetic materials.
Unfortunately, static discharge damage is actually a fairly rare
cause of computer problems. On the bright side, however, a discharge
as low as 200 volts is sufficient to destroy a chip, and this level
of charge can easily be accumulated in just a few steps on carpet.
Static discharge can only be felt when the charge gets up around the
2000 volt mark, so it's possible for a truly adept user to
unknowingly destroy several components in one session.
If the user employs an anti-static discharge strap connected to an
earthed object or simply leaves the computer plugged in (thus
maintaining the chassis earth connection) and takes care to touch
some exposed metal on the power supply before handling
static-sensitive components (and periodically during the job), the
chance of static damage becomes depressingly low.
Old-fashioned belt-drive vacuum cleaners are quite efficient static
electricity generators, so cleaning computer componentry with one is
an excellent way to bolster the income of a service engineer. Newer
cleaners are still good at accumulating static, and are also quite
powerful enough to seriously damage fragile components with sheer
Air force
Electronics stores stock canned "air duster", which is actually
compressed difluoroethane gas, and can be used to clean various
devices. Air duster is quite useful for cleaning more robust items,
but can also be usefully employed in computer destruction, where it
is more than capable of blowing chips out of sockets, spinning fans
to prodigious speeds and destroying their tiny brushless motor
assemblies, and, of course, redistributing dust from relatively
accessible locations to far more exciting ones, like deep inside
expansion card connectors and CD-ROM drives.
For truly powerful air-blasting, though, the discerning user will
have to employ the services of an air compressor. These can be
rented cheaply from many equipment hire shops, and as well as their
greater power (which can snap a RAM module and its socket right off
the board) offer the added bonus of high-speed water delivery,
provided of course that the user makes sure not to use the
condensation drain valve provided for less focussed operators.
Get it wet!
Contact with plain water is surprisingly unlikely to destroy
computer componentry, unless the device in question is left wet for
a while. Beverages like coffee, tea and (especially) cola are much
more effective, and so it is important to have a tall, unstable
container of one or more of these within elbowing distance of the
work area. Crumbs of food can foul connectors and floppy drive
moving parts, but intensive open-mouthed chewing over the computer
is required for a reliable kill.
Killing chips
If the job involves inserting or removing socketed chips, the
options for destruction of expensive devices open up enormously.
Inserting and removing Pin Grid Array (PGA) processor chips in Zero
Insertion Force (ZIF) sockets is unlikely to break anything, unless
the user somehow manages not to operate the locking lever and forces
the issue. PGA chips in old-style sockets are easier to damage; PGA
pins are annoyingly hard to bend, but the forest of pins under the
processor gives many chances to bend just one and make the chip
If the computer is an 80486-based system, the Central Processing
Unit (CPU) can be plugged into its socket in more than one way. One
corner of the processor is bevelled and the matching corner of the
socket will also be marked, but if these markings are disregarded -
or if the user decides instead to line up the printing on the CPU
with that on the motherboard - then the processor can be inserted in
one of the three other alignments. This makes the chip's
destruction, possibly with the emission of smoke, quite likely.
Intel regrettably made processor misalignment impossible with the
introduction of the Pentium series, unless of course the
enterprising user is equipped with a mallet.
Conventional Dual Inline Package (DIP) chips, with a rowof pins
along either side, are much more gratifyingly susceptible to damage.
The very best tool for bending and breaking pins on DIP chips is the
inexpensive springy "chip extractor" available at various
electronics stores. U-shaped, the steel tool has an inward bent lip
on the end of each leg, and is designed to hook both ends of a chip
at once, and give the user the impression that it will in fact
extract both ends at once.
This never happens.
When one end of the (usually very firmly inserted) chip comes out of
the socket, the considerable pull being exerted by the user
immediately causes that end to be lifted well clear of the board
while the last few ranks of pins are still plugged in, resulting in
badly bent or broken pins which are difficult to bend back and very,
very difficult to repair.
Truly adept users can also hook a DIP chip extractor under the
socket, not the chip, and bodily rip it from its soldered-in
location. This can lift tracks from the board and render it
practically irreparable, if done with sufficient gusto.
Chips are much less likely to be damaged if a small screwdriver is
used to lever each end in turn up a little at a time, until the
whole chip comes free at once. Those who have purchased stock in
chip makers recommend against this strategy.
The other common kind of chip package is Plastic Leadless Chip
Carrier (PLCC), which is square with a row of contacts on each side
and which fits into a socket somewhat reminiscent of an above-ground
swimming pool. It is difficult to insert these chips incorrectly,
since one corner is bevelled so they can only fit into the socket
one way, and firm pressure snaps them into place annoyingly
It is also hard to break PLCC chips when removing them; a
purpose-built PLCC extractor does it in a snap and has none of the
redeeming danger of the DIP extracting tools, and removing PLCCs by
prying under the corners with a very small screwdriver is annoying,
but not very hazardous. Fortunately, users seldom have to work with
PLCC chips, and the other types are satisfyingly easy to break.
Inserting Single Inline Memory Modules (SIMMs) should be relatively
simple, since SIMM sockets require one only to insert the module at
an angle, then swing it upright until the locking clips click into
place. Fortunately, many PCs are cramped inside and have at least
one SIMM socket fouled by the power supply or other metalwork,
making it more difficult to insert a memory module in that socket
without damaging it or the socket. Inserting modules backwards (even
though they are designed not to fit that way), jamming them straight