Keys and key identification and security.
In the interests of asset protection, the numbers of locks and keys owned by a single entity continuously grows, making it increasingly difficult for that entity to manage those keys. A growing need therefore exists for conveniently identifying, storing, and managing a multitude of keys.
Lock owners have sought methods of attaching identification to keys in a manner that makes the identity indiscernible from mere observation. Electronic memory devices have provided a method by which key owners can continually account for key related events including identification, lock association, access rights, and storage events, such as presence, absence, replacement, or removal from the storage unit. With this information key owners can securely monitor a secure system involving a multitude of keys and locks. Usually memory devices are monitored by a storage unit which serves not only to secure the keys when not in use, but to provide the communication channels between the keys and a managing server. By requiring access codes to open the system and access specific items within the system, not only does the system keep track of who removed a key, and how long it was gone, but also sets off an alarm if the item is overdue in returning. This allows lock owners to monitor who has access to their assets and ensures the assets will likely be returned in a timely manner.
To date these memory devices have been attached to keys and other assets by means of some form of tag. The memory device is affixed to the tag, which is then attached to the asset by means of a wire or a ring. For example, touch memory buttons have been attached to keys by means of either a flat, tongue-like card or a smaller tag. The card is finger-length, and attaches to the asset by means of a ring. While this allows multiple keys to share the same touch memory button, the ring could easily be removed, rendering the identification obsolete. The tag is a bit smaller and attaches the keys by wire, but still allows multiple keys to share the same touch memory button. As opposed to the card, once the wire is sealed within the tag it cannot be re-opened, rendering the assembly tamper evident. However, both of these solutions can be bulky, especially if carrying more than one assembly at a time. Also, to give each individual key a touch memory button would become cumbersome due to the size of the tags and the rings. These shortcomings have left lock owners in search of a compact, tamper-evident method of providing individual keys with unique electronic memory.
The problem of providing a compact, tamper-evident means of combining individual keys with unique electronic memory is solved by an embodiment involving a holder that is made to attach some form of electronic memory identifier to the head of a key. An example of how such a holder can work is the application of touch memory buttons to the heads of individual keys. Once attached, these assemblies can be mounted and read electronically to continually account for the identification, presence, access rights, and removal or replacement of the keys.
Such a holder is preferably manufactured from a durable material and dimensioned to snugly enclose the head of the key. Such a holder could have a fold in the center allowing it to bend such that the opposing faces ends enclose the key head and fasten together. The manner of fastening would be designed to allow a single closure and prevent re-opening or tampering. In the case of touch memory, the holder would fold around the key head and fasten in such a manner that the lip of the memory button is held snugly between the face of the holder and the respective face of the key head. The memory button and key shank would protrude outward, allowing these items to function unhindered. The holder could also have an additional opening through which a key ring could be inserted.
Application of a holder as preferred would not require alteration of the key head in any manner, and thus could occur when the individual keys are either ready for distribution or already distributed and in regular use. A holder meeting the above description would preferably be manufactured at a small thickness, allowing a significant amount of the touch memory button to protrude from the casing, thus increasing functionality of the button. Once attached the touch memory button extends from the holder and is inserted into an electrically conductive mount that serves to both store the key and read information from the touch memory button. The memory button is then made to serve two purposes: one being a unique electronic identification for the individual key, and the other being a means of mounting and securely storing the key.
The key assembly would be comparable in size to the key itself, rendering it compact and less cumbersome for carrying multiples or carrying in small spaces, such as pockets. The ability to connect a key ring would allow a single user to carry multiple keys, each with their own individual electronic memory, on a single key ring. Also, carrying multiple keys would not require the carrying of separate rings and tags for each key, since the electronic memory identifier is affixed to the key itself.
The preferred embodiment disclosed involves a key holder manufactured to attach an electronic memory identifier to the head of a key in a compact, tamper-evident manner. This embodiment preferably involves a holder manufactured from a durable material and dimensioned to compactly attach to the head of the key. This holder preferably fastens to the key and to the memory device in such a manner as to make any separation tamper evident. Such a holder and its implementation are illustrated in
The embodiment illustrated in
The holder 20 illustrated in
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A combination such as the one illustrated in
Touch memory buttons are not the only form of electronic memory that can be attached to a key head using the proposed method. The opening through the holder can be resized or removed at the manufacturing phase to adapt the holder to different forms of memory devices. A similar holder could also be manufactured consisting of two separate pieces that, when joined together, create an opening through which the key shank extends. The holder can fasten in a variety of manners, including but not limited to flanges, snaps, clasps, pins, adhesives, and epoxy. Such a holder can also be created in varying thicknesses and without any sort of opening for the insertion of key rings. However, any of these alternatives still provide a compact, tamper-evident means of combining individual keys with unique electronic memory for both identification and mounting purposes.
Number | Name | Date | Kind |
---|---|---|---|
5311757 | Spahn | May 1994 | A |
5768925 | Ozawa et al. | Jun 1998 | A |
5775148 | Layton et al. | Jul 1998 | A |
6232876 | Maloney | May 2001 | B1 |
D456852 | Maloney | May 2002 | S |
6392543 | Maloney | May 2002 | B2 |
6424260 | Maloney | Jul 2002 | B2 |
6637245 | Bolton | Oct 2003 | B1 |
6707380 | Maloney | Mar 2004 | B2 |
6862908 | Seki | Mar 2005 | B2 |
6927670 | Gokcebay et al. | Aug 2005 | B1 |
7036950 | Freeman et al. | May 2006 | B1 |
20010020896 | Higuchi | Sep 2001 | A1 |
20030000267 | Jacob et al. | Jan 2003 | A1 |
20030051520 | Janssen et al. | Mar 2003 | A1 |
20030159481 | McGuire et al. | Aug 2003 | A1 |
20050229662 | Banks | Oct 2005 | A1 |
20080258869 | Ognjenovic | Oct 2008 | A1 |
Number | Date | Country | |
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20140048606 A1 | Feb 2014 | US |