Patent Application
20170159327
The invention relates to locks, in particular, locks having a bolt made of two elements, displaceable with respect to one another.
Combination locks commonly comprise a mechanism requiring the input of a certain combination code (buttons pressed at a certain order, combination of digits etc.), subject to which a latch of the lock is free to displace into an open position thereof.
One example of a combination lock is disclosed in U.S. Pat. No. 6,718,803 to the Applicant.
Acknowledgement of the above references herein is not to be inferred as meaning that these are in any way relevant to the patentability of the presently disclosed subject matter.
In accordance with one aspect of the subject matter of the present application, there is provided a lock comprising a housing, a locking mechanism, a locking member configured for displacement with respect to the housing between a closed position and an open position, defining respective open and closed states of the lock, and a bolt configured for displacing between an unlocked position in which the locking member is free to displace between its closed and open positions, and a locked position in which the bolt prevents displacement of the locking member between its open and closed positions, wherein said bolt comprises a follower and an arresting bar attached to one another and configured for displacement as a single body, the follower being configured for engaging a portion of the locking member and wherein:
In general, the locking mechanism is configured, upon providing the proper input (inserting the right key, setting the right combination, pressing buttons in the right order etc.) for assuming an unblocked state, allowing the bolt to freely displace into its unlocked position by virtue of displacement of the locking member
In particular, the lock can be a lock and comprise a locking mechanism similar to that disclosed, for example, in U.S. Pat. No. 6,718,803 to the Applicant.
The follower and the arresting bar can be configured for disengagement with respect to one another under a predetermined threshold load applied to either of the two members.
In particular, application of a load to the follower which is under the threshold load, will cause either of the following:
However, when the arresting bar is held in place (i.e. when the proper input has not been provided), application of a load greater than the threshold load will entail disengagement of the follower from the arresting bar, bringing the lock into a malfunction state in which:
The threshold load can be determined based on the attachment arrangement between the follower and the arresting bar.
In accordance with one design embodiment, engagement between the follower and the arresting bar is in the form of a fixed attachment, whereby disengagement between the follower and the arresting bar takes place as a result of mechanical failure of a fail element, e.g. tearing or breaking off, in which case the threshold load is determined according to the physical properties (material, geometry etc.) of the fail element.
According to one example, the fail element can be constituted by a portion of one of the follower and arresting bar, received within a corresponding recess formed in the other of the components. In this case, when the threshold load (or greater) is applied, the fail element breaks off its component.
According to another example, the fail element can be a separate element, independent of the follower and arresting bar, and configured for fixedly attaching them to one another. In this case, when the threshold load (or greater) is applied, mechanical integrity of the fail element is lost, and the follower is free to displace with respect to the arresting bar.
In connection with the above, the fail element can be made of materials having a lower toughness or hardness compared to the follower. With particular reference to the first example, the arresting bar can be made of a hard metal having a first hardness and configured for preventing egress of the locking member into its open position, wherein the follower can be made of a metal having a second hardness, lower than the first hardness, and configured to fail under the threshold load. The follower can even be made of a softer material such as plastic etc.
It is important to note that the fail element should be, on the one hand, sufficiently strong in order to maintain engagement with the arresting bar during normal operation of the lock and transfer the loads applied thereto by the cam portion of the locking member to the arresting bar in order for the bolt to displace properly, and, on the other hand, to be sufficiently softer than the arresting bar so as to tear/break under the application of the threshold load or higher.
In accordance with another design embodiment, engagement between the follower and the arresting bar is in the form of a coupling, whereby disengagement between the follower and the arresting bar takes place as a result of decoupling, in which case the threshold load is determined according to the strength of the coupling.
The follower can have at least one follower surface configured for engaging a corresponding cam portion of the locking member. In particular, the arrangement can be such that axial movement of the locking member (during engagement between the cam portion and the follower surface) entails lateral movement of the follower, and, subsequently, of the entire bolt.
Thus, it is appreciated that the interaction between the locking member and the bolt is achieved via engagement between the locking member and the follower, i.e. in the unlocked state displacement of the locking bar entails displacement of the bolt via engagement with the follower.
Thus, the arresting bar of the bolt takes no operative part in engagement with the locking member and in affecting said displacement, and serves as a passive component, being driven owing to its attachment to the follower (both moving as a single body).
Therefore, the bolt is configured for performing at least the following basic functions, each configured for being performed by a different, independent component of the bolt:
Thus, the follower can be designed according to specific requirements associated with the displacement of the bolt while the arresting bar can be designed according to specific requirements associated with the ability of the arresting bar to block the locking member. In particular, the materials of which each of the arresting bar and the follower are made can be chosen in accordance with their designated function.
This arrangement can provide the lock with several unique advantages, which cannot be achieved if the entire bold is constituted by a single body made of a single material. For example, while the arresting bar can be required to be made of a sufficiently strong/hard/tough material in order to withstand forced prying of the lock (pulling out of the locking member by force), the follower can be required to be made of a material providing low friction with the locking member in order to reduce wear and tear of the lock during repeated operation.
If the entire bolt were made of a single material, the advantages associated with the operation of displacement of the bolt could have yielded disadvantages in terms of the operation of arresting of the bolt, and vise versa, advantages associated with the operation of arresting of the bolt could have yielded disadvantages in terms of the operation of displacement of the bolt.
In accordance with a particular example, the arresting bar of the bolt can be made of a material having a hardness, for example, a range of hard metals or steels chosen according to the required security level of the lock. The hardness can be chosen to meet specific security level standards.
The follower can be made of a material having a low friction coefficient allowing smooth engagement with the locking member. More specifically, the material of the follower can be chosen from a variety of polymeric and non-polymeric materials, including (but not limited to) rubber and plastic materials. It should be noted here that since the follower is designed so as to reduce friction against the locking member, the reference to ‘material’ can also refer to a coating/s applied to the follower in order to reduce friction.
Thus, according to another aspect of the subject matter of the present application there is provided a lock comprising a housing, a locking mechanism, a locking member configured for displacement with respect to the housing between a closed position and an open position, defining respective open and closed states of the lock, and a bolt configured for displacing between an unlocked position in which the locking member is free to displace between its closed and open positions, and a locked position in which the bolt prevents displacement of the locking member between its open and closed positions, wherein said bolt comprises a follower and an arresting bar attached to one another and configured for displacement as a single body owing to engagement between the locking member and the follower, wherein the follower and the arresting bar comprise different materials.
The locking member can pass at least through the arresting bar such that, in the closed position, at least its cam portion is located axially beyond the arresting bar. Correspondingly, the arresting bar be formed with an opening having an egress portion configured for allowing axial removal of the cam portion through the arresting bar, thereby bringing the lock into its open state, and an arresting portion configured for preventing axial removal of the cam portion through the arresting bar.
The arrangement is such that in the locked position of the bolt, the arresting portion of the opening is aligned with the cam portion of the locking member, and in the unlocked position of the bolt, the egress portion of the opening is aligned with the cam portion of the locking member.
In operation, from the closed state of the lock and locked position of the bolt, axial displacement of the locking member entails engagement of the cam portion with the follower. This may yield the following:
In both cases, the arresting portion of the opening remains aligned with the cam portion of the locking member, thereby preventing its egress from the arresting bar, which, in turn, leaves the lock closed.
It is appreciated that in the second example, the lock becomes malfunctioned, as the follower disengages from the arresting bar and therefore cannot affect it anymore to displace into the unlocked position. Thus, this renders the lock jammed' and unusable.
In accordance with a specific design embodiment, the lock can be a padlock, whereby the locking member can be a shank constituting a portion of a U-shaped shackle.
In order to better understand the subject matter that is disclosed herein and to exemplify how it may be carried out in practice, embodiments will now be described, by way of non-limiting example only, with reference to the accompanying drawings, in which:
It is appreciated that although the specific examples shown in and described with respect to the above mentioned figures refer to a combination lock, the subject matter of the present application can be implemented in any type of lock in which a bolt is incorporated.
Attention is first drawn to
Turning now to
The lock 1 further comprises a bolt 30 received within the housing, and configured for selectively engaging the shackle 20 in order to prevent retraction thereof from the housing 10, and consequently preventing unlocking of the lock 1.
With particular reference being made to
In particular, the bolt 30 is configured for performing a lateral displacement between a first position preventing extraction of the cam portion 25 from the housing 10 and a second position allowing such extraction.
With additional reference being made to
Reverting now to
From this position, pulling on the shackle 24 entails axial movement of the cam portion 25 in an upwards direction. As a result, the cam surface 26 bears against the corresponding cam surface 46 of the follower 40, applying a load thereto attempting to displace the follower 40 laterally to the right.
Assuming a proper combination has been entered into the lock, the arresting bar 50 is free to displace together with the follower 40, resulting in the lateral rightward movement of the entire bolt 30 to the position shown in
In the position shown in these figures, the bolt 30 has displaced to a sufficient amount so that the cam portion 25 of the shank 24 is located directly under the egress portion 54, allowing further extraction of the cam portion 25, thereby unlocking the lock 1.
It is also noted that in this position, both follower 40 and arresting bar 50 maintain the same relation with respect to one another (i.e. have no relative displacement therebetween), as more clearly shown in
However, from the same position shown in
As a result, the lock 1 will assume the position shown in
It should be noted that in order to allow opening of the lock, the arresting bar 50 should be displaced laterally. This displacement is originally induced by displacement of the follower 40 (due to its connection with the bar 50 via the fail element 48), and displacement of the follower is induced by its interaction with the cam portion 25 of the shackle 20.
This, once the follower 40 is disengaged from the arresting bar 50, the latter cannot displace into a desired position and the lock 1 becomes ‘jammed’. The housing 10 does not allow access to the arresting bar 50 (for security reasons) and therefore the lock 1 becomes ‘damaged’ or ‘malfunctioned’ with now way of reverting it back to its original position.
It is also noted that the structural integrity of the fail element 48 is designed according to the expected loads applied to the arresting bar 50 by the follower 40. In other words, the fail element 48 is configured for failing under the application of a load above a certain threshold, which defines the difference between a ‘gentle’ pull on the shackle and a violent attempt of pulling out the shackle by force.
Turning now to
It is observed that the combination mechanism 101 is retained within a housing comprising a first housing component 110 and a second housing component 120 configured for forming a full enclosure of the combination mechanism 101.
Each of the housing components 110, 120 is in the form of a shell 112, 122 respectively, each such shell 112, 122 having a first port 114, 124 configured for receiving therein a first leg of the shackle 20 and a second port 116, 126 configured for receiving therein the second leg of the shackle 20.
The first shell 112 is configured for being received within the second shell 122 so that the first ports 114, 124 are aligned with one another and the second ports 116, 126 are also aligned with one another, allowing insertion of the legs of the shackle through both ports simultaneously.
Turning now to
In assembly, once the sleeves 130, 140 are inserted into the above ports, a purposed tool is used to form outer and inner flange portions for each of the sleeves—134, 136 for the first sleeve 130 and corresponding 144, 146 for the second sleeve 140.
The flange portions prevent axial displacement of the sleeves 130, 140 with respect to the ports, and also facilitate securing the two shells 112, 122 to one another in a manner closing off the housing and preventing access to the combination mechanism 101.
It is noted that the presence of the sleeve within the ports prevents lateral displacement of the housing components 112, 122 with respect to one another, thereby preventing disengagement of the components from one another and disassembly of the housing.
In addition, the use of sleeves allows for the use of shackles 20 of various diameters (of the cross-section of the leg of the shackle) using the same housing components 110, 120. Specifically, if a smaller diameter of the shackle is required, a thicker sleeve can be used so that the shackle leg and sleeve made up a diameter corresponding to that of the ports.
Furthermore, the arrangement of housing components 110, 120 which are separate from the combination mechanism (used only to encapsulate it), allows for simplifying manufacture and reducing costs during the quality assurance tests etc. Specifically, such tests can be performed on the combination mechanism 101 itself (without the encapsulating shell), and once performed, the combination mechanism can be encapsulated in the housing.
| Number | Date | Country | Kind |
|---|---|---|---|
| 233319 | Jun 2014 | IL | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/IL2015/050640 | 6/23/2015 | WO | 00 |
