U.S. patent application number 13/224907 was filed with the patent office on 2011-12-22 for electromechanical cylinder lock.
This patent application is currently assigned to Medeco Security Lock, Inc.. Invention is credited to Peter Field, Duncan Kerr.
Application Number | 20110308285 13/224907 |
Document ID | / |
Family ID | 25179241 |
Filed Date | 2011-12-22 |
United States Patent
Application |
20110308285 |
Kind Code |
A1 |
Field; Peter ; et
al. |
December 22, 2011 |
ELECTROMECHANICAL CYLINDER LOCK
Abstract
An electromechanical cylinder lock includes an outer lock shell
and a rotatable lock barrel located therein which is controlled by
dual locking features. A side bar or fence selectively blocks and
permits rotation of the barrel with respect to the shell in
response to insertion of a key into a keyway in the barrel. A
slider bar is movable between a blocking position in which the side
bar is prevented from permitting rotation of the barrel, and an
unblocking position in which the side bar permits rotation of the
barrel. Alternately, a blocking mechanism is provided to block
motion of tumbler pins in the cylinder lock. A shape memory alloy
actuator, such as a wire made of nitinol, disposed in the barrel is
activated by an electric current in response to determination by an
electronic control device whether an attempt to open the lock is
authorized. Thermal interlock protection from external heating of
the lock is also provided.
Inventors: |
Field; Peter; (Salem,
VA) ; Kerr; Duncan; (San Francisco, CA) |
Assignee: |
Medeco Security Lock, Inc.
Salem
VA
|
Family ID: |
25179241 |
Appl. No.: |
13/224907 |
Filed: |
September 2, 2011 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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12976475 |
Dec 22, 2010 |
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13224907 |
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12724013 |
Mar 15, 2010 |
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12976475 |
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08800742 |
Feb 14, 1997 |
7690231 |
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12724013 |
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Current U.S.
Class: |
70/281 |
Current CPC
Class: |
E05B 51/005 20130101;
Y10T 70/20 20150401; Y10T 70/7616 20150401; E05B 47/063 20130101;
Y10T 70/7079 20150401; Y10T 70/7667 20150401; Y10T 70/7684
20150401; Y10T 70/713 20150401; E05B 47/0009 20130101; F16C 2202/28
20130101; Y10T 70/7119 20150401; Y10S 292/66 20130101 |
Class at
Publication: |
70/281 |
International
Class: |
E05B 47/06 20060101
E05B047/06 |
Claims
1. An electromechanical lock cylinder, comprising: an outer shell
having a bore formed therein and a cavity extending from the bore
into the shell; a barrel disposed within the bore in the shell and
being rotatable relative thereto; a side bar cooperating between
the shell and the barrel for selectively permitting and blocking
rotation of the barrel with respect to the shell, the side bar
having a first portion engaging the barrel and a second portion
removably received in the cavity in the shell, the side bar being
movable relative to the barrel and the shell; a blocking mechanism,
located in said barrel, positionable in a blocking position in
contact with the side bar, which position blocks retraction of the
side bar from the cavity in the shell, and thereby prevents
rotation of said barrel, and also positionable in an unblocking
position relative to the side bar, which permits the side bar to be
retracted from the cavity in the shell to allow the barrel to be
rotated with respect to the shell; an electrically activated drive
mechanism cooperating with the blocking mechanism to selectively
move the blocking mechanism from the blocking position to the
unblocking position in which the side bar moves out of the cavity
upon rotation of the barrel; and control means for activating the
electrically activated drive mechanism in response to an authorized
attempt to operate the lock cylinder.
Description
CROSS REFERENCE TO RELATED APPLICATION
[0001] This application is a continuation of U.S. patent
application Ser. No. 12/976,475, filed on Dec. 22, 2010, which is a
continuation of U.S. patent application Ser. No. 12/724,013, filed
on Mar. 15, 2010, which is continuation of U.S. patent application
Ser. No. 08/800,742, filed on Feb. 14, 1997, now U.S. Pat. No.
7,690,231, the entire disclosures of which are incorporated herein
by reference.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The present invention relates generally to an
electromechanical cylinder lock and, in particular, to a cylinder
lock in which an electrical actuator is employed to provide access
to the lock cylinder.
[0004] 2. Description of Related Art
[0005] Electromechanical locking devices are known which include
electrically interfaced or controlled release mechanisms for
operating a lock cylinder. For example, U.S. Pat. No. 4,712,398
discloses an electronic locking system comprising a lock cylinder
with a rotatable plug located therein. An electronically activated
release assembly is provided which selectively disengages a locking
pin from the plug to allow turning of the key to rotate the plug
relative to the cylinder. The lock cylinder and key each include an
electronic memory device containing keying system codes. Upon
insertion of the key the release mechanism disengages the locking
pin from the plug to allow its rotation. U.S. Pat. No. 5,552,777
discloses another type of electromechanical cylinder lock having a
blocking pin and an electromagnetic solenoid in the cylinder plug.
The blocking pin extends into a recess in the cylinder shell, and
is retracted upon actuation of the solenoid by a microprocessor in
the key.
[0006] One benefit of including electronic control features in
locks is the ability to provide increased keying codes for
operating the lock. For example, information can be stored in the
lock and/or key such that the locking mechanism is activated in
response to detecting and/or exchanging data. As the information
stored in the components may be altered, it is possible to vary the
keying codes without changing the system hardware. In contrast,
changing the mechanical keying codes in a purely mechanical lock
typically requires forming a new key with different bitting
surfaces, a more involved process than reprogramming electronic
components of an electromechanical lock.
[0007] Despite progress made in the development of prior art
electromechanical locking systems, several deficiencies exist which
leave room for improvement. For example, prior art systems do not
provide the ability to retrofit a purely mechanical lock to form an
electromechanical lock which is operated at least in part by
information stored in a key and/or lock cylinder. The benefits of
retrofitting a mechanical lock in this manner include preventing
the need to alter the keying of the lock should it become necessary
to change the combination, for example when an employee loses his
or her key or leaves an establishment. In such a case, the
components of the lock may be reprogrammed to change the keying
codes to prevent the employee's key from operating the lock.
Additionally, prior art systems using electromagnetic components
such as solenoids have been found to be impractical, because of the
small space available and the relatively large size of components
needed to develop enough force to release the blocking mechanism.
Accordingly, there remains a need in the art for an improved
electromechanical cylinder lock system.
SUMMARY OF THE INVENTION
[0008] The present invention provides an electro-mechanical
cylinder lock having at least one, and preferably dual locking
features. The lock includes an outer shell or cylinder member, a
plug or barrel rotatably mounted within the shell, and a plurality
of tumbler pins which are lifted to a shear line of the barrel and
shell to operate the lock. A side bar or fence member is provided
and cooperates between the shell and barrel to selectively block or
permit rotation of the barrel. The side bar has an outer edge
located in a recess formed in the shell and is spring biased toward
the recess. In a blocked position, the side bar prevents rotation
of the barrel. To permit rotation of the barrel, the side bar is
moved out of the cavity and toward the barrel by a camming action
in order to permit rotation of the barrel. The side bar is
prevented from being cammed by a slider bar positioned against the
side bar. When an authorized key is inserted into the lock, a
controller device in the lock activates an actuator mechanism to
move the slider bar to a position over a recess in the side bar,
thus allowing the side bar to be cammed into the barrel by rotation
of the barrel.
[0009] The controller device, for example a microprocessor located
within or outside the barrel, has data stored therein including
authorized codes for operating the lock. The control device
compares data read or detected from the user's key with the stored
data to determine whether the actuator mechanism should be
activated to move the slider bar to an unblocking position with
respect to the side bar. The lock cylinder can include a keyway and
a plurality of tumbler pins, the keyway receiving a key which is
bitted to position the pins at a shear line which permits the
barrel to be rotated.
[0010] Alternatively, the locking mechanism may be of a type which
does not utilize tumbler pins. The key is provided with means for
storing data, for example, a microchip, magnetic data-encoded
strip, and the like, such that upon insertion into the keyway the
controller device compares data transmitted by the key to determine
whether the attempt to operate the lock is authorized, and if so,
activates the actuator mechanism to move the slider bar to an
unblocking position.
[0011] In a preferred embodiment, the actuator mechanism includes a
length of shape memory alloy material (one example of which is
nitinol wire) attached to the slider bar and electrically coupled
to the controller device. Shape memory alloy is a material which
can be set to deform when heated. For example, a length of nitinol
wire may be formed such that upon heating, such as by passing a
small amount of current through the nitinol wire, the wire will
contract, causing the slider bar to be moved to the unblocking
position, allowing the side bar to be cammed by rotation of the
cylinder barrel.
[0012] An important benefit of the invention resides in the fact
that the side bar, slider bar and electrically powered actuator
device are entirely (or substantially entirely) contained within
the barrel. This permits the entire barrel to be removed and placed
in the outer shells of different lock cylinders. The invention
permits the barrel to be substituted for the barrel of a purely
mechanical cylinder lock to retrofit the lock into an
electromechanical lock system. In addition, the invention
contemplates utilizing different but interchangeable
electromechanical barrels with a plurality of lock cylinders in a
lock system. Moreover, the compact, removable barrel may carry some
or all of the electronic hardware, firmware and/or software
associated with the lock to provide even greater flexibility in
various applications.
[0013] According to another aspect of the present invention, a
thermal interlock mechanism is provided to prevent attempts at
circumventing a heat-actuated lock release through external heating
of the lock, by disabling the lock upon such external heating.
BRIEF DESCRIPTION OF THE DRAWINGS
[0014] Other objects, features and benefits of the invention will
become apparent from the detailed description of preferred
embodiments set forth below, taken in conjunction with the
accompanying drawing figures, wherein:
[0015] FIG. 1 is a rear elevation view in section of a lock
cylinder including a shell, a rotatable plug containing movable
locking members, and a side bar constructed according to one
embodiment of the present invention, the movable locking members
and side bar being oriented in a cylinder locking position;
[0016] FIG. 2 is an exploded view of the side bar locking mechanism
assembly according to a first embodiment of the present
invention;
[0017] FIGS. 3A and 3B are three dimensional views of the side bar
assembly according to the first embodiment of the present
invention, in a locked and unlocked position, respectively;
[0018] FIG. 4 is an exploded view of the side bar locking assembly
according to a second embodiment of the present invention;
[0019] FIGS. 5A and 5B are three dimensional views of the side bar
assembly according to the second embodiment of the present
invention, in a locked and unlocked position, respectively;
[0020] FIGS. 6-9 are three dimensional views of various
configurations of pusher and rocker mechanisms for the slider bar
actuator device of the present invention;
[0021] FIGS. 10-12 are views of various configurations for
non-resettable thermal interlocks for the actuator device of the
present invention;
[0022] FIGS. 13-15 are view of various configurations for
resettable thermal interlocks for the actuator device of the
present invention;
[0023] FIG. 16 is a perspective view of a cylinder barrel according
to the present invention, illustrating one possible location for
the controller device;
[0024] FIG. 17 is a circuit block diagram showing one embodiment of
a data carrying key for use with the present invention;
[0025] FIG. 18 is a circuit block diagram showing one embodiment of
the electronics of the lock which controls activation of the shape
memory alloy actuator device; and
[0026] FIG. 19 is a partial phantom top view of an alternative
embodiment of the invention wherein a shape memory alloy actuator
device is used in conjunction with a tumbler pin blocking mechanism
instead of a side bar blocking mechanism.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0027] With reference to FIG. 1, a first embodiment of the present
invention is indicated generally by the reference numeral 10 and
includes a cylinder or outer shell 20 having a bore 22 in which is
positioned a rotatable barrel or plug 30. The barrel 30 has an
outer surface substantially corresponding to the bore 22 of the
shell and includes a keyway 34 configured to receive a key as is
known in the art. The barrel 30 includes a plurality of tumbler pin
bores which receive tumbler pins (not shown) as is known in the
art. The manner in which a properly bitted key (not shown) engages
the tumbler pins and positions them at a shear line to permit the
barrel 30 to be rotated with respect to the shell 20 is known in
the art and thus will not be described in any great detail herein.
However, it should be noted that the tumbler pins may be simply
lifted by the bitting surfaces on the key, or they may be lifted
rotatively by a key including skew cut bitting surfaces, such as
that used with a Medeco.RTM.-type cylinder lock, such as disclosed
in U.S. Pat. No. 4,732,022, incorporated herein by reference in its
entirety.
[0028] The shell 20 includes a cavity 24 in which is positioned a
side bar or fence 60 which cooperates with the barrel 30 to either
block or permit rotation of the barrel within the shell. As
discussed below, the upper wall of the cavity 24 is formed as a
camming surface for moving the side bar out of the barrel upon
rotation of the barrel. As can be seen in FIG. 1, the side bar is
received in cavity 24 and its inner edge extends beyond the
internal surface of shell bore 22 and engages the barrel 30 to
prevent the barrel from rotating to operate the lock. However, when
the slider bar 50 is moved to the unblocking position shown in FIG.
3B, the barrel may be rotated to cam side bar 60 out of cavity 24
so as to clear the inner surface of bore 22 and permit rotation of
the barrel 30 with respect to the shell 20.
[0029] As described in the '022 patent, one or more side bar
springs (not shown) may be positioned between the inner edge of the
side bar 60 and the barrel. The springs bias the side bar into
cavity 24, and the slider bar 50 blocks the side bar from being
cammed and thereby prevents the barrel from rotating.
[0030] FIG. 2 is an exploded view of a side bar assembly according
to a first embodiment of the present invention. The assembly
includes side bar 60, and an actuator device including a slider bar
50, a rocker 70, a shape memory alloy wire 80, a pusher 90, and a
spring 100.
[0031] In one preferred embodiment, the shape memory alloy wire 80
is made of nitinol. Nitinol is a shape memory alloy material (made
of a NiTi alloy) which undergoes a crystalline phase change when
heated, causing it to contract or to expand, depending on whether
the material is pre-stressed to be in a compressed state or a
stretched state. The phase change occurs almost instantaneously at
a specific temperature, which can be specified in commercial grades
of nitinol wire. Nitinol wire is commercially available, for
example from Dynalloy, Inc. under the trade name Flexinol.
[0032] While the use of nitinol is described hereinafter as the
shape memory alloy material for purposes of illustration of a
preferred embodiment of the invention, it will be noted that the
present invention is not limited to the use of nitinol, but may be
implemented by using any other appropriately suitable material.
Examples of other known shape memory alloy materials include
Cu--Al--Ni, Fe--Mn--Si--Cr--Ni, and Cu50--Zr50. Shape memory alloy
materials are also commercially available from Shape Memory
Applications, Inc., Santa Clara, Calif.
[0033] As shown in FIG. 3A, the slider bar 50 is normally biased by
spring 100 in a blocking position with respect to side bar 60, such
that the side bar cannot be cammed out of the cavity 24 in the
shell and thus preventing rotation of the barrel. As shown in FIG.
3B, upon activation of the nitinol wire 80, by passing a
predetermined amount of electric current through it, the wire 80
will contract, pulling rocker 70 against pusher 90, which pushes
slider bar 50 against the force of spring 100 to a position over a
recess 61 in the side bar 60. As such, the side bar 60 may be
cammed into the barrel by rotation of the barrel, allowing the lock
to be opened.
[0034] Preferred specifications for nitinol actuator wire to
perform 100,000+ cycles are as follows:
TABLE-US-00001 maximum strain 4% maximum contraction stress ~25,000
psi biasing stress ~5,000 to 10,000 psi transition temperature 60
to 110.degree. C.
[0035] It is possible to over stress the wire if it is heated too
quickly and is subjected to a high inertial load when it starts to
contract. The wire also can be overstressed if it is prevented from
contracting to its full strain point while being heated to its
transition temperature. Appropriate design considerations can
eliminate these possibilities.
[0036] The rocker and pusher components provide a lever arm
arrangement which serves to provide the appropriate amount of
displacement of the slider bar in response to the maximum tolerable
contraction strain on the length of nitinol wire available for use
in a typical cylinder barrel volume. Some possible variations on
the design of the rocker and pusher components are shown in FIGS.
6-9. As shown in FIG. 6, rocker 70a has a groove for accommodating
the nitinol wire 80 (formed into a crimped loop as shown in FIG.
7B). The rocker 70a abuts against an integral slider and pusher
element. FIG. 7A shows a rocker 70b having ball-shaped ends for
facilitated motion. FIG. 8 shows a "bent pin" rocker configuration
70c, and FIG. 9 illustrates a "turned groove" rocker configuration
70d, wherein the nitinol wire is crimped to the rocker for more
secure operation.
[0037] An alternative embodiment of the side bar assembly according
to the present invention is shown in FIGS. 4, 5A and 5B. In this
embodiment, the nitinol wire actuator 81 is used to pull a
transverse slider bar 51 in a direction perpendicular to the side
bar 60. A slider insulator 52 is inserted into an aperture in the
slider bar 51 and the nitinol wire is threaded through the
insulator 52, as shown in FIGS. 5A-5B. A plug insulator 53 is
attached to the end of the nitinol wire or to the plug itself. A
spring 101 is inserted into another aperture in the slider bar 51
and serves to maintain slider bar 51 normally biased such that an
extension on the side bar 60 (not shown in the view) is located
below recess 54 in the slider bar 51, as shown in FIG. 5A. When the
nitinol wire 81 is actuated, the contraction of the wire forces the
slider bar 51 down against the force of the spring 101, causing the
extension on the side bar to be aligned with the recess 54 as shown
in FIG. 5B, thereby allowing the barrel to be rotated, camming the
side bar into the barrel.
[0038] Because the shape memory alloy actuator is activated by
heat, if the lock were to be heated externally it may be possible
to activate the wire. Accordingly, it is necessary to provide an
external heat interlock mechanism to prevent external heating of
the lock from improperly activating the nitinol wire to operate the
lock. FIGS. 10-12 show various non-resettable heat interlocks. As
shown in FIG. 10A, a low melting temperature solder 110 connects
the nitinol wire to the controller device in the barrel. FIG. 10B
shows low melt solder 111 provided as a cap on the pusher 90. In
the event of external heating, the solder will melt, rendering the
actuator mechanism inoperable. FIG. 11 shows a nitinol ring
interlock 112 which is mounted in or adjacent to the plug. The
nitinol ring 112 is prestressed to have a diameter such that a post
63 provided on side bar 60 is normally able to pass into or through
the ring 112 when the side bar is actuated. However, in the event
that the lock is externally heated, the ring 112 will shrink and
will either clamp around post 63 or block post 63 from entering
into the ring, thus preventing the side bar 60 from being actuated.
FIG. 12 shows a nitinol spring 114 which is prestressed in a
contracted state and is mounted adjacent to a notch 64 in a leg of
side bar 60. If the lock is externally heated, the spring 114 will
expand into the notch 64, thereby preventing the side bar from
being retracted. Ring 112 and spring 114 as shown are single cycle
interlocks, in that once triggered they render the lock permanently
disabled. However, it is possible to configure the ring 112 and
spring 114 such that they will return to their prestressed state
once they return to room temperature, thereby resetting the
lock.
[0039] FIGS. 13-15 show resettable heat interlocks using various
configurations of bimetallic strips. As shown in FIGS. 13A-13C, a
preloaded bimetallic strip 115 may be provided adjacent to the side
bar, which when heated will move to block the side bar, preventing
movement. FIG. 13B shows the orientation of the bimetallic strip
115 relative to the side bar 60 at room temperature (viewed from
inside the plug), allowing the side bar to be retracted (in a
direction perpendicular to the drawing surface). FIG. 13C shows the
orientation of the strip 115 when heated. In this instance, the
strip 115 will flex upward into the path of the side bar 60,
preventing it from being retracted (i.e., preventing the side bar
from moving in the perpendicular direction out of the page). The
thermal interlock shown in FIGS. 13A-13C must be externally reset
once triggered. FIGS. 14 and 15 show automatically resetting
bimetallic strips 116 which act in opposition to the nitinol wire
when heated externally, also preventing the side bar from being
moved. As soon as the bimetallic strips cool to their ambient
temperature, they return to their normal positions, thus allowing
the lock to be reset.
[0040] Examples of the electronic control circuitry for actuating
the nitinol wire is shown in FIGS. 17 and 18. These diagrams
correspond to one preferred electronic security system control as
disclosed in U.S. Pat. No. 5,140,317, also incorporated by
reference herein in its entirety. However, any equivalent
electronic control circuit may be used without departing from the
invention.
[0041] FIG. 17 is a schematic block diagram illustrating the
components within an electronic key housing 104. The components
include a microcontroller or microprocessor 501, an electrically
erasable programmable read only memory (EEPROM) 502 coupled to the
controller 501, an oscillator or clock 503 which provides clock
signals for the operation of controller 501, and a battery power
source 504 which operates the controller 501. The battery 504 may
also be used to provide power to the circuitry within the lock.
However, the lock may be provided with its own battery power source
under appropriate circumstances. The electronic key components
further include an electronic switch 505 operated by the controller
501 and a power sensing circuit 506.
[0042] FIG. 18 is a representative schematic block diagram of
electronic circuitry 208 within the lock. An example of the
location of the circuitry is shown in FIG. 16. This circuitry
includes a microprocessor 601, an EEPROM 602 coupled to the
microprocessor 601, an oscillator or clock 603 for providing
operational clock signals to the microprocessor 601, a power filter
604, electronic switch 605 and load 606 for transmission of signals
to the key controller 501 via line 607, and an electronic switch
608 for allowing power to flow from power source 504 within the key
housing 104 through cable 107 and contacts 103-206 through the
nitinol wire 80 to ground, to activate the nitinol wire.
Alternatively, the power source for the nitinol wire may be a
separate battery located within the lock cylinder or cylinder
barrel, or external to the cylinder.
[0043] In operation, the microprocessor 601 within the lock makes a
determination as to whether the key inserted into the keyway is
authorized to operate the lock, based upon a comparison of data
received from the key with data stored in the memory associated
with the microprocessor 601. The data used for comparison may be
generated pseudorandomly by the microprocessor 601 in accordance
with a stored algorithm.
[0044] In summary, the invention permits conventional mechanical
locks to be retrofitted into electro-mechanical locks. For example,
a conventional lock, which includes a plurality of tumbler pins
that are both raised to a shear line and rotated to a position to
accept the legs of a side bar by inserting a properly bitted key
into the keyway, can be retrofitted by replacing the barrel with an
electromechanical barrel constructed according to the invention.
The electromechanical barrel includes a keyway with a plurality of
tumbler pins and a slider bar, the slider bar being moved by a
nitinol actuator mechanism so as to permit the side bar to be
retracted and the lock operated. In this manner, a purely
mechanical lock, which is subject to the limitations discussed
above, may be retrofitted into an electromechanical lock which
provides the benefits associated with utilizing an electronically
controlled locking feature.
[0045] FIG. 19 illustrates an alternative embodiment of the present
invention wherein a shape memory alloy actuator is used in
conjunction with a tumbler pin blocking mechanism. According to
this embodiment, a spinner 700 which engages a notch 712 in a
tumbler pin 710 is provided in the plug 30. The spinner 700 is
biased into the notch 712 by a spring force 704. A shape memory
alloy actuator 706 is provided to actuate a slider 708 which
engages a boss 702 on the spinner 700.
[0046] In operation, at least one tumbler pin 710 is blocked or
locked into the "up" position (i.e., through the shear line) by the
spinner 700 being engaged in the notch 712. Upon insertion of an
authorized key and successful transfer of data to the control
device, the shape memory alloy actuator 706 is heated by passing a
current therethrough, causing the actuator to contract. The
contraction of the actuator 706 causes it to force the slider 708
against the spinner boss 702 in opposition to and overcoming the
spring force 704. This causes the spinner 700 to rotate to the
position shown in phantom in FIG. 19, disengaging it from the
tumbler pin 710, and allowing the tumbler pin to fall and seat
against the bitting of the inserted key. If the key bittings match
the tumbler pin codes, the key will be able to rotate the plug and
open the lock. When the actuator 706 cools, the spring force 704
will again bias it against the tumbler pin 710, such that as the
key is removed from the plug, the pin will be raised by the
retreating bitting surface of the key, causing the notch 712 to
align with the spinner 710. As the notch 712 lines up with the
spinner 710, the spring force 704 causes the spinner to engage the
notch and again block the pin in an upward position within the
plug.
[0047] The embodiment of FIG. 19 also includes thermal interlock
protection. The ends of the shape memory alloy actuator 706 are
anchored to bosses 720 extending from notches 722 of rotating pins
716. The pins 716 are biased by spring forces 718 to keep the
actuator 706 taut against the slider. A shape memory alloy thermal
interlock actuator 714 is also anchored to the bosses 720. The
actuator 706 is made of a high transition temperature, low force
wire, while the thermal actuator 714 is made of a low transition
temperature, high force wire.
[0048] In the event that the lock is heated externally, the thermal
interlock actuator 714 will contract, pulling in the bosses 720
against the spring forces 718 and creating slack in the actuator
706. Subsequent activation of the actuator wire 706 will thus
merely absorb the imposed slack, preventing the actuator 706 from
exerting enough force to move the slider 708 so as to disengage the
spinner 700. The thermal interlock is automatically resettable, in
that as the plug cools, the thermal actuator 714 will stretch back
to its normal shape, allowing the spring forces 718 to rotate the
pins 716 to remove the slack in the actuator 706.
[0049] Those skilled in the art will recognize the many advantages
and great flexibility provided by the present invention. It should
be recognized that the preferred embodiments discussed above have
been described in detail so as to provide a full and complete
disclosure thereof, and are only exemplary of the many possible
variations and applications of the teachings of the present
invention.
* * * * *