The present invention relates to cylinder locks, and more particularly, to programmable cylinder locks.
The development of security locks has focused for a number of years on not only enhancing the intricacy of the primary coding between the key and the lock mechanism, but furthermore, in developing secondary coding which must also be satisfied in order for the lock to operate properly. Moreover, in some instances a further security feature is provided, according to which an unauthorized key is trapped during an attempt to operate the lock.
Although these prior techniques are effective for their intended purpose of enhancing the security of the lock, the enhanced security features typically involve somewhat intricate machining of components or complex placement of components during assembly of the lock. Furthermore, the particular coding necessary for authorized operation of the lock must with typical prior art techniques, be established in the lock by the lock manufacturer or distributor. This complexity increases the cost of the lock system, and often limits the flexibility and timeliness of the installation and/or replacement of high security locks.
It is accordingly an object of the present invention, to provide a programmable cylinder lock system that has enhanced security and preferably key trapping features.
It is a particular object of the invention that the core portion of the cylinder lock be programmable in the field, by a locksmith or an installer.
It is a further object of the invention that the programmability and enhanced security be implemented in a relatively simple yet clever manner, that does not require intricate machining or complex assembly by either the lock manufacturer or the installer.
It is a further object to provide a key blank having an enhanced security coding that can readily be manufactured, but which if imitated without authority, will not only fail to operate, but can optionally be trapped.
According to a broad aspect of the invention, a plurality of programmable cut outs extend from the outer surface of the core to penetration of at least one keyway sidewall at an intermediate angle to the cylinder axis, each programmable cut out having an associated support surface within the core intermediate the core surface and the keyway. An activator insert is locatable in at least one of the programmable cut outs. The activator insert has an outer portion adjacent the core surface and an inner portion that can freely enter into the keyway. It is displaceable in the cut out between a rest position wherein an unauthorized (or no) key is in keyway, the inner portion is in the keyway, and the outer portion is recessed from the core surface, and an active position wherein a properly coded key is in the keyway, the inner portion of the insert bears on a laterally or obliquely projecting node in the key, and the outer portion is at the core surface. A filler insert is locatable in each of the remainder of the programmable cutouts. Each filler insert has an outer portion at the core surface and an inner portion supported by the support surface such that the filler insert cannot enter into the keyway.
If an unauthorized key successfully fully enters the keyway but is not coded for proper activation of the activator insert, rotation of the core can be initiated but upon registration of a programmed cutout with a shell tumbler, the tumbler will cross the shear line, enter the cutout, and prevent further rotation. If the key is properly coded, the activator insert will be displaced by the key to the core surface, thereby bridging the cut out at the surface, preventing the shell tumbler from crossing the shear line and thus maintaining clearance at the shear line. The filler inserts maintain the bridge under all conditions.
The cutouts and inserts can take a variety of forms. For example, the cut outs can be slots or bores, and the inserts can be plates or pins. The cutouts and associated support surfaces can have any form that accomplishes several purposes: (a) under some conditions define a recess at the core surface that can receive a shell tumbler across the shear line, (b) under other conditions the recess can be bridged by a programmable insert in the presence of a properly programmed key in the keyway to maintain clearance in the shear line, and (c) providing a shelf for supporting a filler insert that bridges the recess whether or not a properly programmed key is in the keyway. The recesses can be in the form of distinct counter bores, or other recessed shapes that can overlap across two or more cutouts, thereby permitting use of a unitary filler insert that spans multiple cutouts. If key trapping is not desired, the edges of the recesses at the core surface can be cambered to facilitate raising of the fallen shell tumbler upon reverse rotation of the key and core.
In an inventive cylinder having a plurality of cutouts penetrating from the core surface to the keyway, and the availability of a plurality of activator inserts and filler inserts, the installer can locate one or more activator inserts pins in any of the cutouts, and one or more filler inserts in the remaining cutouts, to thereby define a code to be provided in the respective flank or flanks of an authorized key. Preferably at least three such cutouts are provided on at least one side of the core, but as a practical matter, four or more cutouts on each side of the core offers sufficient variations to thwart all but the most sophisticated attempts at gaining unauthorized entry.
Preferably, five cutouts on each side of the core are fitted with a pattern of activator inserts and filler inserts, whereas a sixth cutout on each side, closest to the back end of the core, is fitted with a blocking insert. The cut out for the blocking insert need not be of the same type as for programming, i.e., the activator cutouts can be slots whereas the cutouts for pin-type blocking inserts can be bores.
In various embodiments, the present invention is directed to a programmable cylinder lock system, a programmable core for a cylinder lock, a core kit by which the installer can program the core in the field, and a novel key adapted to be used with the programmable core.
The programmable cylinder lock comprises a substantially cylindrical core having front and back ends and a keyway having a key entry at the core front end and sidewalls shaped to closely receive a key blade having opposed top and bottom edges and opposed left and right flanks. A substantially cylindrical shell has a longitudinal bore closely coaxially surrounding the outer surface of the core. The core has a neutral position within the shell such that the keyway top and bottom are at 0 and 180 degree positions, respectively, relative to the axis when viewed from the keyway entry and the core can rotate within the shell bore when a properly coded key is fully inserted in the keyway. A plurality of tumbler bores are located in the shell and penetrate the shell bore at a 0 degree angle relative to the neutral position of the core. A respective plurality of tumblers are located in the tumbler bores and biased toward the shell bore so as to contact the core. A plurality of programmable cut outs extend from the outer surface of the core to penetration of at least one keyway sidewall at an intermediate angle to the axis. Each programmable cut out has as associated support surface within the core. An activator insert is situated in at least one of the cutouts and has an outer portion adjacent the core surface, and an inner portion that can freely enter into the keyway. The activator insert is displaceable in the cut out between a rest position wherein no key is in the keyway, the inner portion is in the keyway, and the outer portion is recessed from the core surface, and an active position wherein a properly programmed key is in the keyway, the inner portion of the insert bears on the key, and the outer portion is at the core surface. A filler insert is in each of the remainder of the programmable cut outs. Each filler insert has an outer portion at the core surface and an inner portion supported by the support surface such that the filler insert cannot enter into the keyway.
The programmable core for a cylinder lock comprises a substantially cylindrical core having an outer surface, front and back ends and a keyway having a key entry at the core front end and extending along the core longitudinal axis toward a core back end. The keyway has opposed top and bottom walls and opposed left and right sidewalls shaped to closely receive a key blade having opposed top and bottom edges and opposed left and right flanks, such that the keyway top and bottom are at 0 and 180 degree positions, respectively, relative to the axis when viewed from the keyway entry. The outer surface of the core has at least three left side cut outs between but not including the 0 and 180 degree positions and extending from the outer surface of the core to penetration of the keyway left sidewall, and at least three right side cutouts between but not including the 0 and 180 degree positions, extending from the outer surface of the core to penetration of the keyway right sidewall.
In the preferred embodiment of the cylinder lock, the cut outs are in the form of a plurality of left side slots extending from the outer surface of the core to penetration of the keyway left sidewall, and a plurality of right side slots extending from the outer surface of the core to penetration of the keyway right sidewall. The activator inserts are in the form of plates having a projection into the keyway. Filler members are in at least one left side slot or at least one right side slot. The filler member has a shape for interacting with the slot such that the member cannot enter into the keyway. A key is insertable into the keyway, each of the flanks having a longitudinal channel alignable with the plurality of left side slots and/or right side slots. At least one of the channels has a raised node alignable with the projection on an activator plate, whereby insertion of the key urges the node against the projection, thereby displacing the plate in the slot while the projection remains in the keyway.
The preferred form of the programmable core kit for a cylinder lock is based on the foregoing preferred cylinder lock, wherein the cut outs are defined by a plurality of left side slots extending from the outer surface of the core to penetration of the keyway left sidewall and a plurality of right side slots extending from the outer surface of the core to penetration of the keyway right sidewall. A plurality of activator plates are insertable in at least one of a left side slot or a right side slot, each activator plate having a substantially semi-circular shape with the diametrical portion adjacent the keyway and the arcuate portion adjacent the core outer surface, the diametrical portion having a transverse projection for entering into the keyway. A plurality of filler members are insertable in each of the remainder of the programmable cut outs, each filler member having an outer portion at the core surface and an inner portion supported by the support surface such that the filler member cannot enter into the keyway.
One aspect of a key according to the invention comprises a bonnet for grasping with fingers, a blade extending in a longitudinal direction from the bonnet to a distal tip, and having top and bottom edges spaced apart along a blade height direction and left and right opposed flanks defining a cross sectional profile. The profile forms a longitudinally extending upper rectangular region having a substantially vertical upper wall on one flank, a longitudinally extending lower rectangular region having a substantially vertical lower wall on that one flank, and a longitudinally extending intermediate region between the upper and lower rectangular regions. The intermediate region defines a longitudinally extending channel zone on the one flank that is in relief relative to the upper and lower walls. At least one raised node is situated in the channel zone, each node having a front ramp facing the tip of the blade, a back ramp facing the bonnet, and an actuator surface between the front ramp and the back ramp. The actuator surface has an orientation that is oblique with respect to the upper and lower walls.
In another aspect of the inventive key for insertion into a cylinder lock keyway the blade has top and bottom edges spaced apart along a blade height direction and left and right flanks spaced apart along a blade width direction. A longitudinal channel is formed in at least one flank, having a width extending in the blade height direction and a depth extending in the blade width direction. At least one raised node is situated in the channel, each node having a front ramp facing the tip of the blade, a back ramp facing the bonnet, a side face between the front and back ramps defining a substantially flat side surface substantially parallel to the blade height direction, and an actuator surface contiguous with the front ramp, back ramp, and side surface.
The preferred embodiment of the invention will be described in greater detail with reference to the accompanying drawings, in which:
The present invention is an improvement to, and is based on, a conventional cylinder lock having a substantially cylindrical core for rotation within a substantially hollow cylindrical shell when a properly coded key is fully inserted within a coded keyway in the core. A conventional cylinder will not be further described herein, because one of ordinary skill in the art is very familiar with the way in which the bits on the top edge of a key blade cooperate with tumblers arranged between the shell and core to block the rotational shear line between the shell and the core when no key is present, and to clear the shear line when a properly bitted key is present.
The present invention provides an additional level of coding associated with the flank of the blade, and the portions of the core and shell which are not normally involved with the conventional cooperation of the key bits with the associated tumblers.
A first embodiment of the invention in a variety of forms including programmable cylinder, programmable cylinder lock, programmable cylinder system, and associated programmable key, will be described with respect to
As shown in
A key 30 having a bonnet portion 32 for grasping between the fingers, and a blade portion 34 extending from the bonnet, has a top edge 36, a bottom edge 38 and left and right flanks 46, 48 defining a thickness corresponding to the width of the keyway as established by the opposed left and right side walls. The left flank 46 has a recessed longitudinal channel portions of which are indicated at 40A and 40B, and the right flank 48 has a right side longitudinal channel, a portion of which is indicated at 40C. In the illustrated embodiment, the key nodes 42A, 42B, and 42C rise above the left channel so as to lie substantially in the same plane as the planer surface of flank 46. Similarly, node 42D rises from the right channel, into the plane of right side flank 48.
Each of the pin bores 26 has an associated pin located therein, but three different types of pins occupy respective bores. Activator pins 50A, 50B and 50C have an overall length substantially equal to the length of the pin bore, and the shape of this type pin interacts with the pin bore such that the pin can freely enter into the keyway in the absence of a confronting node on the key, such as 42A, 42B, and 42C respectively. In particular, the height of the head 56 on the activation pins 50A, 50B, and 50C is less than the height of the counter bore 28, whereby the stem 58 of the activator pin can drop through the pin bore into the keyway, in the absence of a supporting surface at the keyway sidewall. In the presence of such supporting surface, the head portion 56 is flush with the core outer surface. Only one activator pin 50D is provided on the right side of the core, shown with an associated key node 42D. The significance of the activator pins will be discussed below in greater detail.
Preferably adjacent to the back end 16 of the core, a pair of opposed blocking pins 52A, 52B are provided, each having an overall length that is greater than the length of the pin bores, such that when the head of the blocking pin is seated within the respective counter bore, the head is flush with the core outer surface and the pin stem 58 enters into the keyway. In particular, the nose portion 60 of the stem extends into the channel 40B of a properly coded key. It can be appreciated that if the leading portion of a key is not channeled, the key cannot pass beyond the blocking pins and therefore cannot fully insert into the keyway.
Filler pins 54A and 54B, are shown on the left side of the core. Like the blocking pins, the heads on the filler pins are preferably shaped to fill the counter bore while remaining flush with the outer surface of the core, but unlike in the blocking pins, the stem of the filler pin is shortened such that the overall length of the filler pin is no greater than the overall length of the pin bore.
It should thus be understood that, according to the invention, a programmable core installation kit can be provided comprising a core having a plurality of pin bores penetrating from the core surface to the keyway, and a plurality of at least the activator pins and filler pins, such that the installer can locate one or more activator pins in any of the pin bores, and one or more filler pins in any of the remaining bores, to thereby define a code to be provided in the respective flank or flanks of an authorized key. Preferably at least three bores are provided on at least one side of the core, but as a practical matter, four or more pin bores provided on each side of the core offers sufficient variations to thwart all but the most sophisticated attempts at gaining unauthorized entry. Preferably, five pin bores on either side of the core are fitted with a pattern of activator pins and filler pins, whereas a sixth pin bore on each side, closest to the back end of the core, is fitted with a blocking pin. Although not likely to be utilized in practice, the invention includes the extreme cases of programming with all pin bores having activator pins or all pin bores having filler pins, or the pin bores being provided on only one side of the core.
The security effect of the activator pins will be described with respect to
For convenience in understanding the further description contained herein, it should be understood that the shell has a longitudinal bore 66 in which the programmed core 44 is closely surrounded such that the core can rotate within the shell bore when a properly coded key is fully inserted into the keyway. The key upper and lower edges 36, 38 are aligned vertically when the core and keyway are in the neutral position, i.e., the keyway top and bottom are at the zero and 180 degree positions, respectively, relative to the axis when viewed from the keyway entry. Thus, the tumbler bore 68 and associated tumbler 70 are at the zero degree angle, the right side pin bores and pin 50D extend along a 90 degree ray from the axis, and the left side pin bore and associated pin 50B extend along a 270 degree ray from the axis. In the plane illustrated in
It can be appreciated that the head of activator pin 50B remains at the outer surface of the core both at the neural position of the core shown in
It should be understood that variations to the illustrated embodiment can be made without departing from the spirit and scope of the claims. For example, the pin bores can be situated at acute angles (other than 90 and/or 270 degrees) relative to the neutral plane of the assembly or the insertion plane of the keyway, so long as the associated pins can interact with a channel and associated node in the flank of a proper key. Such acute angles and the 90 and 270 degree angles can be referred to collectively as “intermediate” angles relative to the zero and 180 degree positions.
The second embodiment of the invention will be described with reference to
In
In
It can be appreciated by inspection of
The displacement of the activator inserts 150 as between the rest condition shown in
In the preferred implementation of this embodiment, each insert is in the form of a flat plate or the like, especially a semicircle having an arcuate outer surface 156, a substantially straight diameter inner portion 158, adjacent the keyway, with the nose portion 160 projecting transversely into the keyway at all times. Upon rotation of the core with properly programmed key it can be appreciated that rotated the shear line 196 remains substantially perfectly circular due to the bridging of the pockets in the cutouts, by the outer surface 156 of the activator inserts.
If key trapping is not desired, the edges of the pockets can be beveled or chamfered as indicated at 204, on the side adjacent the core tumbler bores 176, thereby providing a sloped, rather than right angle surface at the portion of the shelf tumbler 170 that has entered the pocket.
A further optional feature includes provision of blocking pins to prevent full insertion of a non-milled key. As shown in
In the embodiment shown in
The preferred key associated with the second embodiment of the invention will now be discussed with particular reference to
To facilitate this compound movement, the front ramp 180 forms a front notch 188 with the channel and the back ramp 182 forms a back notch 190 with the channel. The notches define respective front and back transition slopes leading to the actuator surface 186. The transition slopes 188, 190 are substantially triangular, with the apex contiguous with the actuator surface.
The channel width is indicated at 192 in
To facilitate smooth insertion of the key while the projections of the activator inserts are in the channels, the surface 206 on which the projection rides until it reaches the ramp, can also be angled in a manner analogous to the oblique angle of the activator surface 186. Furthermore, it can also be appreciated that the difference in the dimensions 192 and 194 shown in
This inventive concept for the key can be expressed more generally with respect to
Regardless of the shape of the channel zone, the zone is formed by milling to achieve the relief relative to the vertical upper and lower walls 216, 218 on the respective upper and lower regions. At least one raised node 142b is situated in the channel zone, having the ramps 182 and actuator surface 186 as previously discussed, preferably with the actuator surface having an orientation that is oblique with respect to the upper and lower walls of the profile. It is most convenient for manufacturing purposes, if the outer edge 208 of the actuator surface is vertically aligned with one of the walls, in particular, with the lower wall 212. It can also be seen that the activation surface 186 is spaced from the upper region 216.
The broken boundary lines on three sides of the portion of the key depicted in
The inventive key is generalized to an even greater extent in the schematic shown in
The solid lines represent any given key milling profile, and in this case a section line is shown through opposing nodes. The hidden dashed lines represent portions of the channels which extend inwardly and outwardly from the plane of the paper. The phantom dashed line represents the solid key blank (billet) prior to milling of the key. Thus, in the illustrated schematic, the upper region has a left side wall that has been milled relative to the original billet left flank, whereas the milling on the right side leaves a portion at the billet right flank. Similarly, the lower region of the key, especially near the bottom edge, leaves material in original left and right billet flanks. In the left side channel zone, the side face of the node is at the billet left flank line, whereas the side face of the right side node has been milled flat relative to the original right side flank line.
The inventive key can be implemented according to the invention within a multi-variable window, of the following parameters:
The node height should never be higher than the FR or FL billet flanks, however, the node(s) may be highest plane on a particular side of a key. A regular profile milling may mill away the material in all areas except the node area itself.
WR and/or WL could (technically) continue down to the bottom of the key without affecting functionality of the key, as long as the node ramp is still in place.
This application is a continuation-in-part of U.S. App. Ser. No. 10/616,591, filed Jul. 9, 2003, from which the benefit of 35 U.S.C. §120 is claimed.
Number | Date | Country | |
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Parent | 10616591 | Jul 2003 | US |
Child | 10834600 | Apr 2004 | US |