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Chapter 9: Recognizing and Exploiting Personality
Traits
Real locks have a wide range of mechanical features and defects
that help and hinder lock picking. If a lock doesn't respond
to scrubbing, then it probably has one of the traits discussed
in this chapter. To open the lock, you must diagnose the trait
and apply the recommended technique. The exercises will help
you develop the mechanical sensitivity and dexterity necessary
to recognize and exploit the di�erent traits.
9.1 Which Way To Turn
It can be very frustrating to spend a long time picking a lock
and then discover that you turned the plug the wrong way. If
you turn a plug the wrong way it will rotate freely until it
hits a stop, or until it rotates 180 degrees and the drivers
enter the keyway (see section 9.11). Section 9.11 also explains
how to turn the plug more than 180 degrees if that is necessary
to fully retract the bolt. When the plug is turned in the correct
direction, you should feel an extra resistance when the plug
cam engages the bolt spring.
The direction to turn the plug depends on the bolt mechanism,
not on the lock, but here are some general rules. Cheap padlocks
will open if the plug is turned in either direction, so you
can chose the direction which is best for the torque wrench.
All padlocks made by the Master company can be opened in either
direction. Padlocks made by Yale will only open if the plug
is turned clockwise. The double plug Yale cylinder locks generally
open by turning the bottom of the keyway (i.e., the at edge
of the key) away from the nearest doorframe. Single plug cylinder
locks also follow this rule. See Figure 9.1. Locks built into
the doorknob usually open clockwise. Desk and ling cabinet locks
also tend to open clockwise.
When you encounter a new kind of lock mechanism, try turning
the plug in both direc- tions. In the correct direction, the
plug will be stopped by the pins, so the stop will feel mushy
when you use heavy torque. In the wrong direction the plug will
be stopped by a metal tab, so the stop will feel solid.
9.2 How Far to Turn
The companion question to which way to turn a lock is how far
to turn it. Desk and ling cabinet locks generally open with
less than a quarter turn (90 degrees) of the plug. When opening
a desk lock try to avoid having the plug lock in the open position.
Locks built into doorknobs also tend to open with less than
a quarter turn. Locks which are separate from the doorknob tend
to require a half turn to open. Deadbolt lock mechanisms can
require almost a full turn to open.
Turning a lock more than 180 degrees is a diffcult because the
drivers enter the bottom of the keyway. See section 9.11.
9.3 Gravity
Picking a lock that has the springs at the top is di�erent than
picking one with the springs at the bottom. It should be obvious
how to tell the two apart. The nice feature of a lock with the
springs at the bottom is that gravity holds the key pins down
once they set. With the set pins out of the way, it is easy
to nd and manipulate the remaining unset pins. It is also straight
forward to test for the slight give of a correctly set pin.
When the springs are on top, gravity will pull the key pins
down after the driver pin catches at the sheer line. In this
case, you can identify the set pins by noticing that the key
pin is easy to lift and that it does not feel springy. Set pins
also rattle as you draw the pick over them because they are
not being pushed down by the driver pin.
9.4
Pins Not Setting
If you scrub a lock and pins are not setting even when you vary
the torque, then some pin has false set and it is keeping the
rest of the pins from setting. Consider a lock whose pins prefer
to set from back to front. If the backmost pin false sets high
or low (see Figure 9.2), then the plug cannot rotate enough
to allow the other pins to bind. It is hard to recognize that
a back pin has false set because the springiness of the front
pins makes it hard to sense the small give of a correctly set
back pin. The main symptom of this situation is that the other
pins will not set unless a very large torque is applied.
When you encounter this situation, release the torque and start
over by concentrating on the back pins. Try a light torque and
moderate pressure, or heavy torque and heavy pressure. Try to
feel for the click that happens when a pin reaches the sheer
line and the plug rotates slightly. The click will be easier
to feel if you use a sti�torque wrench.
9.5
Elastic Deformation
The interesting events of lock picking happen over distances
measured in thousandths of an inch. Over such short distances,
metals behave like springs. Very little force is necessary to
deflect a piece metal over those distances, and when the force
is removed, the metal will spring back to its original position.
Deformation can be used to your advantage if you want to force
several pins to bind at once. For example, picking a lock with
pins that prefer to set from front to back is slow because the
pins set one at a time. This is particularly true if you only
apply pressure as the pick is drawn out of the lock. Each pass
of the pick will only set the frontmost pin that is binding.
Numerous passes are required to set all the pins. If the preference
for setting is not very strong (i.e., the axis of the plug holes
is only slightly skewed from the plug's center line), then you
can cause additional pins to bind by applying extra torque.
Basically, the torque puts a twist in the plug that causes the
front of the plug to be deflected further than the back of the
plug. With light torque, the back of the plug stays in its initial
position, but with medium to heavy torque, the front pin columns
bend enough to allow the back of the plug to rotate and thus
cause the back pins to bind. With the extra torque, a single
stroke of the pick can set several pins, and the lock can be
opened quickly. Too much torque causes its own problems.
When the torque is large, the front pins and plug holes can
be deformed enough to prevent the pins from setting correctly.
In particular, the first pin tends to false set low. Figure
9.2 shows how excess torque can deform the bottom of the driver
pin and prevent the key pin from reaching the sheer line. This
situation can be recognized by the lack of give in the rst pin.
Correctly set pins feel springy if they are pressed down slightly.
A falsely set pin lacks this springiness. The solution is to
press down hard on the rst pin. You may want to reduce the torque
slightly, but if you reduce torque too much then other pins
will unset as the first pin is being depressed.
It is also possible to deform the top of the key pin. The key
pin is scissored between the plug and the hull and stays xed.
When this happens, the pin is said to be false set high.
9.6 Loose Plug
The plug is held into the hull by being wider at the front and
by having a cam on the back that is bigger than the hole drilled
into the hull. If the cam is not properly installed, the plug
can move in and out of the lock slightly. On the outward stroke
of the pick, the plug will move forward, and if you apply pressure
on the inward stroke, the plug will be pushed back.
The problem with a loose plug is that the driver pins tend to
set on the back of the plug holes rather than on the sides of
the holes. When you push the plug in, the drivers will unset.
You can use this defect to your advantage by only applying pressure
on the outward or inward stroke of the pick. Alternatively,
you can use your nger or torque wrench to prevent the plug from
moving forward.
9.7 Pin
Diameter
When the pair of pins in a particular column have different
diameters, that column will react strangely to the pressure
of the pick.
The top half of Figure 9.3 shows a pin column with a driver
pin that has a larger diameter than the key pin. As the pins
are lifted, the picking pressure is resisted by the binding
friction and the spring force. Once the driver clears the sheer
line, the plug rotates (until some other pin binds) and the
only resistance to motion is the spring force. If the key pin
is small enough and the plug did not rotate very far, the key
pin can enter the hull without colliding with the edge of the
hull. Some other pin is binding, so again the only resistance
to motion is the spring force. This relationship is graphed
in the bottom half of the Figure. Basically, the pins feel normal
at rst, but then the lock clicks and the pin becomes springy.
The narrow key pin can be pushed all the way into the hull without
loosing its springiness, but when the picking pressure is released,
the key pin will fall back to its initial position while the
large driver catches on the edge of the plug hole.
The problem with a large driver pin is that the key pin tends
to get stuck in the hull when some other pin sets. Imagine that
a neighboring pin sets and the plug rotates enough to bind the
narrow key pin. If the pick was pressing down on the narrow
key pin at the same time as it was pressing down on the pin
that set, then the narrow key pin will be in the hull and it
will get stuck there when the plug rotates.
The behavior of a large key pin is left as an exercise for the
reader.
9.8 Beveled
Holes and Rounded pins
Some lock manufacturers (e.g., Yale) bevel the edges of the
plug holes and/or round o�the ends of the key pins. This tends
to reduce the wear on the lock and it can both help and hinder
lock picking. You can recognize a lock with these features by
the large give in set pins. See Figure 9.4. That is, the distance
between the height at which the driver pin catches on the edge
of the plug hole and the height at which the key pin hits the
hull is larger (sometimes as large as a sixteenth of an inch)
when the plug holes are beveled or the pins are rounded. While
the key pin is moving between those two heights, the only resistance
to motion will be the force of the spring. There won't be any
binding friction. This corresponds to the dip in the force graph
shown in Figure 5.5.
A lock with beveled plug holes requires more scrubbing to open
than a lock without beveled holes because the driver pins set
on the bevel instead of setting on the top of the plug. The
plug will not turn if one of the drivers is caught on a bevel.
The key pin must be scrubbed again to push the driver pin up
and o�the bevel. The left driver pin in Figure 9.6 is set. The
driver is resting on the bevel, and the bottom plate has moved
enough to allow the right driver to bind. Figure 9.6 shows what
happens after the right driver pin sets. The bottom plate slides
further to the right and now the left driver pin is scissored
between the bevel and the top plate. It is caught on the bevel.
To open the lock, the left driver pin must be pushed up above
the bevel. Once that driver is free, the bottom plate can slide
and the right driver may bind on its bevel.
If you encounter a lock with beveled plug holes, and all the
pins appear to be set but the lock is not opening, you should
reduce torque and continue scrubbing over the pins. The reduced
torque will make it easier to push the drivers o�the bevels.
If pins unset when you reduce the torque, try increasing the
torque and the picking pressure. The problem with increasing
the force is that you may jam some key pins into the hull.
9.9 Mushroom Driver
Pins
A general trick that lock makers use to make picking harder
is to modify the shape of the driver pin. The most popular shapes
are mushroom, spool and serrated, see Figure 9.7. The purpose
of these shapes is to cause the pins to false set low. These
drivers stop a picking technique called vibration picking (see
section 9.12), but they only slightly complicate scrubbing and
one-pin-at-a-time picking (see chapter 4).
If you pick a lock and the plug stops turning after a few degrees
and none of the pins can be pushed up any further, then you
known that the lock has modi�ed drivers. Basically, the lip
of the driver has caught at the sheer line. See the bottom of
Figure 9.7. Mushroom and spool drivers are often found in Russwin
locks, and locks that have several spacers for master keying.
You can identify the positions with mushroom drivers by applying
a light torque and pushing up on each pin. The pins with mushroom
drivers will exhibit a tendency to bring the plug back to the
fully locked position. By pushing the key pin up you are pushing
the flat top of the key pin against the tilted bottom of the
mushroom driver. This causes the driver to straighten up which
in turn causes the plug to unrotate. You can use this motion
to identify the columns that have mushroom drivers. Push those
pins up to sheer line; even if you lose some of the other pins
in the process they will be easier to re-pick than the pins
with mushroom drivers. Eventually all the pins will be correctly
set at the sheer line.
One way to identify all the positions with mushroom drivers
is to use the at of your pick to push all the pins up about
halfway. This should put most of the drivers in their cockable
position and you can feel for them.
To pick a lock with modified drivers, use a lighter torque and
heavier pressure. You want to error on the side of pushing the
key pins too far into the hull. In fact, another way to pick
these locks is to use the flat side of your pick to push the
pins up all the way, and apply very heavy torque to hold them
there. Use a scrubbing action to vibrate the key pins while
you slowly reduce the torque. Reducing the torque reduces the
binding friction on the pins. The vibration and spring force
cause the key pins to slide down to the sheer line.
The key to picking locks with modiffed drivers is recognizing
incorrectly set pins. A mushroom driver set on its lip will
not have the springy give of a correctly set driver. Practice
recognizing the difference.
9.10 Master
Keys
Many applications require keys that open only a single lock
and keys that open a group of locks. The keys that open a single
lock are called change keys and the keys that open multiple
locks are called master keys. To allow both the change key and
the master key to open the same lock, a locksmith adds an extra
pin called a spacer to some of the pin columns. See Figure 9.8.
The e�ect of the spacer is to create two gaps in the pin column
that could be lined up with the sheer line. Usually the change
key aligns the top of the spacer with the sheer line, and the
master key aligns the bottom of the spacer with the sheer line
(the idea is to prevent people from filing down a change key
to get a master key). In either case the plug is free to rotate.
In general, spacers make a lock easier to pick. They increase
the number of opportunities to set each pin, and they make it
more likely that the lock can opened by setting the all the
pins at about the same height. In most cases only two or three
positions will have spacers. You can recognize a position with
a spacer by the two clicks you feel when the pin is pushed down.
If the spacer has a smaller diameter than the driver and key
pins, then you will feel a wide springy region because the spacer
will not bind as it passes through the sheer line. It is more
common for the spacer to be larger than the driver pin. You
can recognize this by an increase in friction when the spacer
passes through the sheer line. Since the spacer is larger than
the driver pin, it will also catch better on the plug. If you
push the spacer further into the hull, you will feel a strong
click when the bottom of the spacer clears the sheer line.
Thin spacers can cause serious problems. If you apply heavy
torque and the plug has beveled holes, the spacer can twist
and jam at the sheer line. It is also possible for the spacer
to fall into the keyway if the plug is rotated 180 degrees.
See section 9.11 for the solution to this problem.
9.11 Driver or Spacer Enters
Keyway
Figure 9.9 shows how a spacer or driver pin can enter the keyway
when the plug is rotated 180 degrees. You can prevent this by
placing the at side of your pick in the bottom of the keyway
before you turn the plug too far. If a spacer or driver does
enter the keyway and prevent you from turning the plug, use
the at side of you pick to push the spacer back into the hull.
You may need to use the torque wrench to relieve any sheer force
that is binding the spacer or driver. If that doesn't work try
raking over the drivers with the pointed side of your pick.
If a spacer falls into the keyway completely, the only option
is to remove it. A hook shaped piece of spring steel works well
for this, though a bent paperclip will work just as well unless
the spacer becomes wedged.
9.12 Vibration Picking
Vibration picking works by creating a large gap between the
key and driver pins. The underlying principle is familiar to
anyone who has played pool. When the queue ball strikes another
ball squarely, the queue ball stops and the other ball heads
o�with the same speed and direction as the queue ball. Now imagine
a device that kicks the tips of all the key pins. The key pins
would transfer their momentum to the driver pins which would
y up into the hull. If you are applying a light torque when
this happens, the plug will rotate when all the drivers are
above the sheer line.
9.13 Disk
Tumblers
The inexpensive locks found on desks use metal disks instead
of pins. Figure 9.10 shows the basic workings of these locks.
The disks have the same outline but di�er in the placement of
the rectangular cut.
These locks are easy to pick with the right tools. Because the
disks are placed close together a half-round pick works better
than a half-diamond pick (see Figure A.1). You may also need
a torque wrench with a narrower head. Use moderate to heavy
torque.
To return to the table of contents, click
here.
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