A cylinder lock is described and, more particularly, a cylinder lock comprising two or more independent locking mechanisms, including conventional tumblers and twisting tumblers and an associated locking bar. Also described is a key for operating the locking mechanisms when placed in a keyway of the cylinder lock.
Cylinder locks for locking doors, cabinets and other structures are well known in the art. Conventional cylinder locks typically include a cylinder shell, and a cylinder plug rotatably disposed within the shell. The interface between the interior surface of the cylinder shell and the exterior surface of the cylinder plug forms a shear surface. A plurality of tumbler pins are reciprocally mounted in chambers extending through the shell and the plug. The tumbler pins are a series of spring-driven segmented pins, including an upper portion and a lower portion. The cylinder lock is in a locked condition when the upper portions of the tumbler pins project across the shear surface preventing the cylinder plug from rotating relative to the cylinder shell.
The cylinder plug has a longitudinal slot or keyway for receiving a key blade of a key. Notches of varying depth along the top of the key blade define a key code for the cylinder lock. A properly configured key blade displaces the tumbler pins to a position where a joint between the upper portion and the lower portion of each pin is aligned with the shear surface. In this position, the cylinder lock is in an unlocked condition, which permits rotation of the cylinder plug relative to the cylinder shell. One portion of each tumbler pin rotates with the plug and the remaining portions of the tumbler pins are stationary within the shell. The cylinder plug is typically coupled with a lock actuator that rotates with the plug for releasing a securing mechanism, such as a dead bolt, upon rotation of the plug.
A second independent locking mechanism can also be provided in the form of a second set of tumbler pins. The second set of tumbler pins may be operated by a corresponding lock code cut in the form of notches of varying depth or angle along the sides of the key blade. The second set of tumbler pins can control a secondary locking structure, including a locking bar positioned in the cylinder plug. The locking bar rests in a camming slot of the cylinder shell preventing relative rotation of the cylinder plug and cylinder shell. When the second set of tumblers are received in corresponding notches of the key blade, the tumblers are displaced transversely permitting rotation of the cylinder plug by a camming action on the locking bar.
A problem with cylinder locks is the spring-driven tumbler pins, which typically comprise small coil springs. As a result, cylinder locks are not fully reliable since the springs may become weaker over time or be damaged as a result of environmental variations.
For the foregoing reasons, there is a need for a cylinder lock with two or more locking mechanisms and a complementary key. The new cylinder lock should provide an improved biasing element that overcomes the problems associated with the use of coil springs.
A lock assembly is provided comprising a lock body including an inner surface defining a bore having a longitudinal axis and a longitudinal slot extending along at least a portion of the inner surface. The lock body defines a plurality of longitudinally spaced pin bores extending substantially perpendicular to the longitudinal axis from an outer surface of the lock body and opening into the bore. A key plug is also provided and defines a longitudinal keyway extending from one end and having an outer surface defining a longitudinal groove. The key plug further defines a first plurality of longitudinally spaced pin bores extending substantially perpendicular to the longitudinal axis of the key plug from the outer surface of the key plug and opening into the keyway, and a second plurality of longitudinally spaced pin bores extending substantially perpendicular to the longitudinal axis of the key plug from the outer surface of the key plug and opening into the keyway. The longitudinal groove in the outer surface of the key plug opens into the second plurality of pin bores. The key plug is rotatably disposed in the bore of the lock body such that in a first position the pin bores in the lock body align with the first plurality of pin bores in the key plug, and wherein the outer surface of the key plug defines a shear plane with the inner surface of the lock body. A first plurality of pins includes a first outer portion and a second inner portion, each of the first portion and the second portion of the pins disposed in one of the pin bores in the lock body and in one of the first plurality of pin bores in the key plug. Means are provided for urging the first plurality of pins toward the keyway such that the first outer portions of the pins span the shear plane to prevent rotation of the key plug relative to the lock body when a key is not in the keyway. A second plurality of pins is provided and having a recess formed therein. Each of the second plurality of pins is disposed in one of the second plurality of pin bores in the key plug for reciprocal or rotational movement about an axis. An elongated spring member simultaneously engages and biases the second plurality of pins toward the keyway. The spring member is disposed in a longitudinal slot defined in the outer surface of the key plug contiguous with the second plurality of pin bores. A locking bar is disposed in the groove in the key plug for movement between a first position where the locking bar is received in the slot in the lock body and a second position where at least a portion of the locking bar is received in the recesses in the second plurality of pins. The locking bar is prevented from moving to the second position unless the second plurality of pins are in a predetermined position where the recesses are aligned for receiving the at least a portion of the locking bar. Means are provided for biasing the locking bar to the first position. Upon insertion of a proper key in the keyway the first plurality of pins are moved axially in the bores in the lock body and the key plug such that the junction between the first portion and the second portion of the first plurality of pins aligns with the shear plane, and the second plurality of pins are moved axially or rotated about their axes for aligning the recesses in the second plurality of pins with the locking bar. Thus, the key can rotate the key plug and the locking bar cams against the slot in the lock body to move the locking bar into the second position where the projections on the locking bar are in the recesses to allow rotation of the key plug.
A locking mechanism is provided for use in a lock assembly including a lock body having an inner surface defining a bore having a longitudinal axis and a longitudinal slot extending along at least a portion of the inner surface. A key plug defines a keyway extending longitudinally from one end and a plurality of longitudinally spaced pin bores extending from the outer surface of the key plug and opening into the keyway. The key plug is rotatably disposed in the bore of the lock body. The locking mechanism comprises a plurality of pins having a recess formed therein, each of the plurality of pins is adapted to be disposed in one of the plurality of pin bores in the key plug for reciprocal and rotational movement about an axis. An elongated spring member simultaneously engages and biases the plurality of pins toward the keyway, the spring member adapted to be disposed in a longitudinal slot defined in the outer surface of the key plug contiguous with the plurality of pin bores. A locking bar is adapted to be disposed in the groove in the key plug for movement between a first position where the locking bar is adapted to be received in the slot in the lock body and a second position where at least a portion of the locking bar is received in the recesses in the plurality of pins. The locking bar is prevented from moving to the second position unless the plurality of pins are in a predetermined position where the recesses are aligned for receiving the at least a portion of the locking bar. Means are provided for biasing the locking bar to the first position. Upon insertion of a proper key in the keyway the plurality of pins are moved axially or rotated about their axes for aligning the recesses in the plurality of pins with the locking bar so the key can rotate the key plug and the locking bar cams against the slot in the lock body to move the projections on the locking bar into the recesses to allow rotation of the key plug.
For a more complete understanding of the present invention, reference should now be had to the embodiments shown in the accompanying drawings and described below. In the drawings:
Certain terminology is used herein for convenience only and is not to be taken as a limitation. For example, words such as “upper,” “lower,” “left,” “right,” “top”, “bottom,” “horizontal,” “vertical,” “upward,” and “downward” merely describe the configuration shown in the FIGs. The terminology includes the words above specifically mentioned, derivatives thereof and words of similar import. Indeed, the components may be oriented in any direction and the terminology, therefore, should be understood as encompassing such variations unless specified otherwise.
The cylinder lock assembly described herein relates to an improvement for a standard cylinder lock. The cylinder lock assembly can also be used in an embodiment with an interchangeable core cylinder. The interchangeable core cylinder is designed with a second shear line and respectively requires a second key to turn the cylinder plug and a control sleeve simultaneously, thus retracting a portion of the control sleeve allowing easy installation and removal of the cylinder plug in a variety of cylinder housing designs for various applications. Since interchangeable core cylinders are described in the prior art, the details of operation will not be covered here.
Referring now to the drawings, wherein like reference numerals designate corresponding or similar elements throughout the several views, a cylinder lock assembly according to one embodiment is shown in
The cylinder plug 24 is cylindrical in shape and is received for rotation about its axis within the bore 34 of the cylinder lock body 22. The cylinder plug 24 defines an axial keyway 40 having a profile for receiving a complementary key blade 114. The cylinder plug 24 has a first plurality of longitudinally-spaced radial chambers 42 that extend transversely to the longitudinal axis of the cylinder plug 24 from the outer surface of cylinder plug 24 and into the keyway 40. The first plurality of chambers 42 of the cylinder plug 24 are aligned with the chambers 36 of the cylinder lock body 22 when the cylinder plug 24 is in the cylinder lock body 22 and in a home position as depicted in
An inner end of the cylinder plug 24 defines a circumferential groove 46 for receiving a retaining ring 48 for retaining the cylinder plug 24 in the cylinder lock body 22. An actuator (not shown), such as a spindle or a torque blade, may be operatively connected for rotation with the cylinder plug 24 for performing a locking or unlocking function, as is known in the art.
The first set of tumbler pins 26 comprises a plurality of conventional split pins, each including axially superimposed upper portions 50 and lower portions 52 having facing end surfaces. The first set of tumbler pins 26 are slidably disposed within the chambers 36 in the cylinder lock body 22 and the first plurality of chambers 42 of the cylinder plug 24. The lengths of the upper and lower portions 50, 52 of the pins 26 vary for defining a first locking code. The first set of tumbler pins 26 are biased by dedicated helical springs 54 compressed between the upper end surfaces of the pins and a retaining plate 56. The retaining plate 56 is press fit, staked or otherwise secured in the groove 38 in the cylinder lock body 22 such that the retaining plate 56 is flush with the outer surface of the lock cylinder body 22 (
Referring to
In another embodiment shown in
The second set of tumbler pins 28 are mounted in the chambers 44 in the side of the cylinder plug 24. Each of the second set of tumbler pins 28 has a longitudinal axis and is slidable axially within their respective chamber 44 relative to the cylinder plug 24. Each of the second set of tumbler pins 28 is also able to rotate about their respective longitudinal axes relative to the cylinder plug 24.
A leaf spring 92 (
In the embodiment shown in the FIGs., there are six chambers 36, 42 common to the cylinder lock body 22 and the cylinder plug 24 for the first set of tumbler pins 26 and five side chambers 44 in the cylinder plug 24 for the second set of tumbler pins 28. More or fewer chambers are possible and may be used if desired, as may any of many different variations of conventional designs for the first set of tumbler pins 28. Such variations include splitting the first set of tumbler pins 28 into more than two portions to accommodate master keying, varying the shapes and dimensions of the tumbler pins 28 to make it more difficult to pick the lock, and the like.
Referring to
As shown in
The second locking mechanism, including the second set of tumbler pins 28 and the locking bar 30, is located in the lower right quadrant of the cylinder plug as seen in
Referring to
Only when a key 110 comprising the proper first code and second code, with bits and notches of the correct predetermined depth and angle, is inserted in the keyway 40 can the first set of tumbler pins 26 and the second set of tumbler pins 28 be properly positioned permitting the cylinder plug 24 to be rotated.
The proper key 110 also causes axial re-positioning of the second set of tumbler pins 28 and rotation of the second embodiment 58 of the set of tumbler pins 28 about their axes by virtue of the chisel-shaped tips 62 biased against the side walls 122 of the notches 120 in the key blade 114. More particularly, the tips 62, 82 of the first embodiment 58 and the second embodiment 78 of the second set of tumbler pins 28 bear against the spaced notches 120 in the side face 118 of the key 110 under the biasing action of the spring 92. The chisel-shaped tip 62 of the tumbler pins 28 will engage with the angled walls 122 defining the notches 102 so as to cause an axial as well as a rotational movement of the tumbler pins 28. The end surface 65 of the tip 62 and the walls 122 of the notches 120 work against one another to rotate the tumbler pins 58. In this manner, the tumbler pins 58 are able to rotate into the notches 120 until the ends of the tips 62 contact both walls 122 of the notches 120. The spring 92 further serves to bias the conical tips 82 of the second embodiment 78 of the second set of tumbler pins 28 into corresponding notches 120 of predetermined depth. In this position, the axial slots 64 and grooves 84 in the body portions 60, 80 of the tumbler pins 58, 78, respectively, will be aligned with the lugs 100 on the locking bar 30 as best shown in
As described herein, a cylinder lock 20 is provided with tumbler pins 28 and a locking bar 30 as a second locking mechanism that operates independently of a first locking mechanism comprising conventional tumbler pins 26. Operation of the cylinder lock 20 is prevented unless a key 110 properly configured for both the first and second locking mechanisms is inserted in the keyway 40. Accordingly, the cylinder lock 20 with the additional locking mechanism provides a high degree of security. A key blank that is merely copied to fit conventional tumbler pins will not open the cylinder lock 20; therefore, the cylinder lock 20 cannot be easily circumvented by unauthorized key duplication. The cylinder lock 20 also offers a high number of different opening combinations, corresponding to an identical number of different keys. The possible lock codes associated with the second locking mechanism involve different combinations of predetermined axial positions and rotational positions of the second set of tumbler pins 28.
Moreover, the cylinder lock 20 described herein is compact, even with a second locking mechanism, and sufficient space remains in the cylinder body 22 for additional locking mechanisms of the same or different designs. For example, the second locking mechanism itself is sufficiently compact that it may be duplicated on the other side of the cylinder plug 24 to provide a tertiary locking code. In this embodiment, the key blade 114 may have code patterns in the form of notches 120 on both side faces 118, 119 for cooperating with tumbler pins arranged on both sides of the keyway 40. Of course, the side code pattern, or patterns, may be combined with any other code patterns anywhere on the key blade 114. In some extremely high security applications it may be desirable to have two or more sets of conventional tumbler pins arranged in the upper quadrants of the cylinder plug 24. It is also possible to provide symmetrical keys which can be introduced in the lock with either side up, and where the code pattern of either side face 118, 119 of the key blade 114 has its “mirror” code pattern on the other side face.
The user also has the option of adapting the cylinder lock to a new key any time that security suggests. The code patterns may be changed several times without the need to remove or replace any of the tumbler pins 28 used in the second locking mechanism.
Although the present invention has been shown and described in considerable detail with respect to only a few exemplary embodiments thereof, it should be understood by those skilled in the art that we do not intend to limit the invention to the embodiments since various modifications, omissions and additions may be made to the disclosed embodiments without materially departing from the novel teachings and advantages of the invention, particularly in light of the foregoing teachings. Accordingly, we intend to cover all such modifications, omission, additions and equivalents as may be included within the spirit and scope of the invention as defined by the following claims. In the claims, means-plus-function clauses are intended to cover the structures described herein as performing the recited function, and not only structural equivalents but also equivalent structures. Thus, although a nail and a screw may not be structural equivalents in that a nail employs a cylindrical surface to secure wooden parts together, whereas a screw employs a helical surface, in the environment of fastening wooden parts, a nail and a screw may be equivalent structures.
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