The present invention relates to the field of keys and locks. More particularly, the invention relates to a key and a lock which do not allow certain break-in operations.
In traditional cylinder locks, an accepted break-in method is as described below:
Stage A: The thief inserts a “key” with maximal projections (“Key D” below), into which the pins of the cylinder are inserted.
Stage B: The thief moves (“bounces”) the pins to the appropriate heights that allow rotating the cylinder and opening the lock.
The purpose of the invention is to prevent the break-in method described above.
It is an object of the present invention to provide a key and a lock not allowing the break-in technique.
It is an object of the present invention to provide a solution to the above-mentioned and other problems of the prior art.
Other objects and advantages of the invention will become apparent as the description proceeds.
A key (10, 10A), comprising:
Encoding characteristics of the at least one (12d) of the encoding bores, designed to allow a corresponding pin (16d) of a lock (44) thereof to cross an entire thickness (50) of the blade (20), may comprise at least location of the bore, and depth of the bore.
The at least one (12c) of the encoding bores, designed to allow a corresponding pin (16d) of a lock (44) thereof to cross an entire thickness (50) of the blade (20), may comprise a stationary dome (48d), protruding beyond the blade's thickness (50).
The at least one (12c) of the encoding bores, designed to allow a corresponding pin (16d) of a lock (44) thereof to cross an entire thickness (50) of the blade (20), may comprise a rotatable protrusion (22),
The encoding characteristics of the at least one (12c) of the encoding bores, designed to allow a corresponding pin (16d) of a lock (44) thereof to cross an entire thickness (50) of the blade (20), may comprise at least the height of the rotatable protrusion (22), and direction of rotation of the rotatable protrusion (22).
The invention is directed to a lock (44) for the key (10, 10A), the lock comprising an indentation (34) encoded for housing the rotatable protrusion (22) for opening the lock (44).
The indentation (34) may comprise a diagonal wall (34A), for rotating the rotatable protrusion (22) to a non-protruding position, for allowing inserting the key (10A) into the lock (44) and for removing the key therefrom.
The rotatable protrusion (22) may be operable for determining the height of two pins (16d, 16e) of a lock (44), according to the pin (16d) having a stronger spring (18d).
The reference numbers have been used to point out elements in the embodiments described and illustrated herein, in order to facilitate the understanding of the invention. They are meant to be merely illustrative, and not limiting. Also, the foregoing embodiments of the invention have been described and illustrated in conjunction with systems and methods thereof, which are meant to be merely illustrative, and not limiting.
Preferred embodiments, features, aspects and advantages of the present invention are described herein in conjunction with the following drawings:
It should be understood that the drawings are not necessarily drawn to scale.
The present invention will be understood from the following detailed description of preferred embodiments (“best mode”), which are meant to be descriptive and not limiting. For the sake of brevity, some well-known features, methods, systems, procedures, components, circuits, and so on, are not described in detail.
The solution of the invention is encoding of protrusions, meaning that the encoding comprises a protrusion or protrusions beyond the thickness of the key blade.
The result is that it is not possible to perform stages A and B described in the background chapter.
One configuration is encoding by means of fixed protrusions. For example, if a key that has only projections has five possible depths for each projection, i.e., five possibilities for each bore, henceforth additional encodings of protrusions are added. For example, two heights of protrusions, adding up to 5+2=7 possibilities.
One of the disadvantages of fixed protrusions is that it is problematic to insert and remove the key. An additional disadvantage is that the protrusion is only from one side.
Another configuration that solves the above problems is that the encoding of the protrusion or protrusions is active only once the key is inserted, i.e., by means of a rotatable protrusion.
The rotatable protrusion configuration achieves encoding that protrudes from both sides of the key.
For example, if a key that has only projections has five possible depths for each projection, i.e., five possibilities for each bore, additional encodings of protrusions are now added. For example, two heights of protrusions from both sides, giving 2+2+5=9 possibilities.
The figure depicts a cross-section of a prior art key (52) and the key handle (14). Key (52) has encoding bores (12a,12b,12c,12d) engraved on the side 32B of the surface of the blade (20). The depth of the bores is different. For example, bore (12c) is deeper than the other bores (12b,12d,12a).
The combination of the depth of the bores (12a,12b,12c,12d) defines the key code, fitting the code of the corresponding prior art cylinder 42.
In this state, of the encoding pins (16a,16b,16c,16d) of cylinder 42 entering into bores (12a,12b,12c,12d) of the prior art key (52), the encoding pins (16a,16b,16c,16d) of cylinder 42 correspond to encoding bores (12a,12b,12c,12d) of prior art key 52. Thus, the encoding pins (16a,16b,16c,16d) of cylinder 42 allow rotation of the drum (not shown), since in this situation, a shear line 26 exists at the other end of the encoding pins (16a,16b,16c,16d).
A break-in key 40, used by a person not having key 52 and the key code thereof, constitutes a key being similar to prior art key 52. However, unlike key 52 having encoding bores (12a,12b,12c,12d) having different depths, in break-in key 40, all of the bores (12a′,12b′,12c′,12d′) are bored in at a maximal depth.
At the first step, break-in key 40 is inserted into the cylinder 42, to which the prior art key of
In this state, of entering the maximal depth into bores (12a′,12b′,12c′,12b′) of break-in key 40, the encoding pins (16a,16b,16c,16d) of cylinder 42 do not correspond to encoding bores (12a,12b,12c,12d) of key 52 of
In the second stage, the thief draws the encoding pins (16a,16b,16c,16d) away along the direction enumerated 46, from the bores (12a′, 12b′, 12c′, 12d′) to a location that is suitable for the encoding in the cylinder, i.e., the ends of encoding pins (16a,16b,16c,16d) approach the shear line (26) and enable opening the cylinder 42.
The method of drawing the encoding pins (16a,16b,16c,16d) away is typically applied in these locks by shaking, bouncing, or inserting and removing of break-in key 40, while applying pressure for rotating the cylinder drum.
The invention is directed to a key and a lock 44 adapted thereto, for preventing this break-in method.
In order for the key (10) not to enable the break-in method described in
This key (10) does not enable the break-in method described in
If bore 12d would have been unchangeable in all the keys of this inventive type, i.e., would not be part of the encoding, the thief would have been able to prepare a break-in key 40 that would contain this deep bore 12d, so that the break-in key 40 would be able to move in this opposite direction. However, the thief cannot prepare such a uniform key, because, according to the present invention, the location of this deep bore varies between the key 10 to key 40, and/or its height may vary.
In contrast to the prior art, key 52 having encoding limited to the thickness of the blade, the inventive key 10 adds combinations of encoding which are not limited to the thickness, since the depth of bore 12d exceeds the thickness 50 of the blade.
The disadvantages of this method are
a. It is difficult to produce such a key (10) that has a protrusion. For a symmetrical key, allowing inserting the key straight or upside-down, as enabled by present day keys, the dome 48d must also be present on the other side (32B). This is even more problematic.
The third disadvantage of the key in
The drum (28) in the cylinder (30) contains two slots (36, 38). These slots must be in the drum (28) in order for the key 10 having projections 48d to enter the slot (36) of the drum (28) and leave it. Also, it is possible to see the first encoding pin (16).
A key (10A) according to this embodiment of the present invention, includes, instead of the stationary dome (48d) of
The rotatable protrusion (22) enters the cylinder drum (28) at a tilted position.
A spring (18d) lifts encoding pin (16d). Spring 18d is designed to be stronger than spring 18e and other springs (18a,18b,18c,18e). Thus, encoding pin (16d) lifts one side (22A) of rotatable protrusion 22 beyond side 32A, and lowers the other side (22B) of rotatable protrusion 22 about a hinge 24. The lowering of side 22B presses encoding pin (16e), thus pushing the pin (16e) downwards.
This action creates additional encoding between the rotatable protrusion (22) and pins (16d) and (16e), and enables pin (16d) to penetrate to the depth that is beyond the thickness 50 of the key, thus avoiding the break-in burglary technique in the customary method (described in
The other encoding pins (16a, 16b, 16c), and springs (18a, 18b, 18c) are similar to those of the prior art cylinder (42 in
Rotatable protrusion (22) is advantaged over the stationary dome (48d) of
Description of the mechanism: The left spring (18d) is stronger than the right spring (16e). Therefore, when the key (10) is disposed inside, the strong spring (18d) dictates the direction of the inflection of the rotatable protrusion (22) to the position depicted in
Upon pulling the key (10) out of the drum (28), the upper side 22A of the rotatable protrusion (22) collides with the diagonal wall 34A of the indentation 34 of the drum (28), and presses the upper side 22A of the rotatable protrusion (22) to descend towards the lower pin (16d). The lower side (22B) of the rotatable protrusion (22) rises and enables pin (16e) to rise.
The descending of upper side 22A of rotatable protrusion (22) by the diagonal wall of indentation 34 is enabled similar to the releasing downwards of the other encoding pins (16a, 16b, 16c) that were inserted in low depth, via the thrust of the conical part into the bores of the key (10).
According to another embodiment, the left spring (18d) may be weaker than the right spring (16e), and therefore when the key (10) is housed inside, the right spring (18e) is the strong one that dictates the direction of the inclination of the rotatable protrusion (22), causing the inclination to be reversed, thus reversing the encoding and adding encoding possibilities.
The rotatable protrusion 22 is releasable by the diagonal wall of indentation 34 of drum 28, even in the case that the rotatable protrusion 22 protrudes towards the drum 28 at the external side (right in the figure) of the key 10A.
The figure shows an example of the key (10A) having two encoding rotatable protrusions (22). This example depicts that another parameter of the encoding is the location of the rotatable protrusion 22 in relation to the key 10A.
An additional parameter is the height of the rotatable protrusion (22).
Similarly, concerning the lower pins (16c, 16e) at the lower sides of the rotatable protrusions (22), each reaches a different depth. So there is encoding in the protrusions from both sides of the key.
An additional parameter is the location and depth of the indentation (34) in the drum (28).
When the key (10) is inserted into the drum (28), the rotatable protrusions (22) rise into the indentations (34) inside the drum (28), and it is part of the encoding of the cylinder. When the rotatable protrusions (22) ascend, a place is vacated for the long encoding pins (16b, 16d) to rise and surpass the height of the key (10), with the back side of the rotatable protrusion encoding pins (16e, 16c). The other encoding pins (16a) encode the familiar encoding method.
Thus, referring to
The bore (12d) may further include a dome (48d) that covers the bore (12d), wherein the height of the dome (48d) is a function of the encoding.
The key (10A) may further include: an additional dome (48d) disposed on the second side of the key, the additional dome (48d) for covering the other bore (12d), wherein the height of the projection depends on the encoding.
The said dome (48d) may be stationary on the key.
Said dome (48d) may constitute a rotatable protrusion body (22), being rotatable about a hinge (24).
Said rotatable protrusion (22) protrudes only when facing the indentation (34) of the drum (28). The hinge (24) allows the rotatable protrusion (22) to be disposed parallel to the blade, for not protruding out, thus allowing inserting and removing the key (10A) from the lock 44.
The rotation direction of the rotatable protrusion (22) is a function of the encoding.
In the figures and/or description herein, the following reference numerals (Reference Signs List) have been mentioned:
In the description herein, the following references have been mentioned:
The foregoing description and illustrations of the embodiments of the invention has been presented for the purposes of illustration. It is not intended to be exhaustive or to limit the invention to the above description in any form.
Any term that has been defined above and used in the claims, should to be interpreted according to this definition.
The reference numbers in the claims are not a part of the claims, but rather used for facilitating the reading thereof. These reference numbers should not be interpreted as limiting the claims in any form.
Number | Date | Country | Kind |
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229188 | Oct 2013 | IL | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IL2014/050842 | 10/22/2014 | WO | 00 |