The present invention relates to electronically-controlled lock systems, and also to cabinet latches; more particularly, to a system for securely latching a cabinet/locker door or drawer with an electronic lock mechanism; and most particularly, to a battery-powered electronic lock system responsive to a card reader or other authorization means, suitable for securely latching of a cabinet/locker door or drawer.
Locking systems for securing cabinet/locker doors and drawers are well known in the prior art. Typically, such a system may comprise a simple spring latch actuated by manual turning of a key in an associated barrel lock.
More sophisticated door locking security systems are known wherein an electro-mechanical latching apparatus may be actuated by a card reader or key pad. The electromechanical mechanism is known to be mounted on either the cabinet/locker door or drawer or within the frame surrounding the cabinet/locker door or drawer. In either embodiment, the latching mechanism is actuated by a linear solenoid or small DC motor powered by an external DC supply, which is difficult for either a door-latching or drawer-latching application wherein the locking mechanism is mounted on the movable member.
Many prior art devices cannot easily be installed to engage with a mating part located above or to the side of the movable member. Most devices in the prior art cannot communicate with a centrally located access control system in a wireless mode. None of the prior art units have the capability of delaying the unlock signal until any preload on the release mechanism has been removed. In that case, the person trying to get into the cabinet or drawer would have to re-enter their code or re-swipe their card after the preload had been removed.
Also, none of the prior art devices have the ability to sense the presence of the locking member in its mating part which is mounted in the top or side wall of the cabinet. Finally, few if any prior art devices have a mechanical key override.
What is needed in the art is an electronic cabinet/locker lock system wherein the mechanism and circuitry are powered only by resident batteries which can be recharged by inductive power transfer, and the system can communicate wirelessly with a remote access control system.
Additionally, the art needs a lock which can be mounted in any of four positions relative to the door/drawer and frame; can sense a preload condition and delay the activation signal until the preload has been removed; sense the presence of the locking member in its locked position; and provide a key override.
It is a principal object of the present invention to securely lock a cabinet/locker door or drawer, and to make such a locking apparatus releasable by card reader or a keypad. Additionally, this lock system could be used on standard entry doors.
Briefly described, a wireless battery operated locking system in accordance with the present invention comprises a first (“external”) assembly disposable on the outside of a cabinet/locker door or drawer and a second (“internal”) assembly disposable on the inside of the cabinet/locker door or drawer.
The external assembly comprises an external cover housing; a rotatable knob having a rectangular shaft extendable through the door or drawer face to mate with the internal assembly; a card/credential reader; a status indicator; a wireless capability to communicate with a remote control center; a wire harness for connecting to the internal assembly; and a jump port plug and cap.
The internal assembly comprises a housing; a shaft rotation link matable with the external knob shaft; a latch bolt assembly connected to the shaft rotation link; a battery-powered circuit board and controller; a battery-powered locking and unlocking mechanism, a mechanical key override feature, a unit locked sensing feature, a preload sensing feature and a battery.
The battery powered locking mechanism includes a rack and pinion gear set linking the shaft rotation link with a latch sleeve supporting the latch bolt. A rotatable blocker inhibits motion of the latch sleeve unless such motion is authorized by the external card/credential reader. Upon such authorization, a battery-powered motor, such as a DC motor, a piezo motor or a linear piezo actuator rotates the blocker 90°, or otherwise linearly displaces the blocker, thereby permitting the latch bolt to be withdrawn from latched engagement with a jamb-mounted strike plate by manual rotation of the knob, shaft, shaft rotation link, and pinion gear (all through a bearing located in the internal module).
The present invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Corresponding reference characters indicate corresponding parts throughout the several views. The exemplification set out herein illustrates one preferred embodiment of the invention, in one form, and such exemplification is not to be construed as limiting the scope of the invention in any manner.
There exists the need for a wireless battery operated locking system that has a spring latch mechanism which automatically locks a cabinet/locker door or drawer when pushed closed. The system must also be able to change to an unlocked state when the system's card reader is presented with valid credentials. Additionally, the system must support being surface-mounted on either a cabinet/locker door or a drawer front face, configured in any of four positions. These positions are in axial rotation about the knob with minimum intervals of 90°, as shown and described more fully below in
Referring to
System 10 includes external assembly 14, including a rotatable knob 16 and internal assembly 18 including a battery-operated locking mechanism 20 mounted on respective outer and inner surfaces 22, 24 of cabinet door 12. An optical or magnetic card/credential reader 26 is disposed in external housing cover 28, with card/credential reader antenna 30, status indicator 32, knob 16 and attached shaft 34, and a jump port plug cap 36. A jump port plug, hidden by the jump port plug cap 36, addresses the issue of occasional low battery power. The jump port is available to apply emergency external power to the system. A wiring harness 38 for connection to internal assembly 18 is connected to reader 26, antenna 30, status indicator 32, and a jump port (not visible) under cap 36. Antenna 30 communicates with a hub connected to a remote access control system (not shown).
Battery-powered locking mechanism 20 comprises cover housing 39, latch bolt 40, shaft rotation link 42, battery cover 44, housing or case 46, sensor switch cover 48, security board cover 50, a small motor assembly 84 (Shown in
Wiring harness 38 connects the external and internal assemblies 14, 18 so that they can communicate with each other and so that electronics in the external assembly can be powered by the battery. Wiring harness 38 is affixed to the external assembly; during installation, harness 38 is fed through a hole in cabinet door 12 then the external assembly is installed on the cabinet door front 22. Wiring harness 38 is then plugged into the internal assembly which then is installed on the inside surface 24 of cabinet door 12. Alternatively, the wiring harness 38 is fed through a through-gap 51 within the internal assembly, with the internal assembly then secured to the inside surface 24 of the cabinet before connecting the wire harness to the internal assembly.
Referring to
Referring to
A blocker 82 attached to motor assembly 84 prevents sleeve 72 from being moved to the unlocked position by rotation of gear 70, as shown in
Referring again to
A cylindrical feature 86 on latch bolt 40 allows the reed switch wires 83 to pass through it, making them concealed and protected while latch bolt 40 moves up and down. Channel 88 in case 46 allows freedom of movement of the wires inside the channel and for the wires to stay connected to a secure board therein (not visible) while latch bolt 40 moves. Channel 88 further functions as a guide, in conjunction with cylindrical feature 86, to limit side to side movement of the latch bolt as the latch bolt moves up and down.
Referring to
In one aspect of the invention, in the case where a premature turning of the knob is followed by an unlock signal from a presentation of the card/credential, the unlock signal to the motor may be stored and applied at a later time once the turn knob pressure is released. In the case of the turn knob having pressure applied when the motor assembly is attempting to relock the unit, the relock signal may also be stored until the pressure has been released from the turn knob. This is particularly important to make certain that the lock has been re-locked and the door or drawer thus secured.
Referring now to
In operation of system 10, when a security card is held up to the reader, the reader sends the card information wirelessly, such as by way of antenna 30 to a remote hub which asks an access control system if the card is valid. The remote hub replies to the cabinet lock system with the validation signal as reported by the access control system. If the card is valid, the external assembly 14 sends an encrypted data packet to the internal assembly, which decodes it and drives motor assembly 84 to unlock the latch. After a set period of time, the latch is relocked by driving motor assembly 84 in an opposite direction.
The circuit board in the internal assembly constantly monitors the switch mounted in the latch bolt to determine if the cabinet door is closed and reports this status back to the circuit board in the external assembly so that the data can be sent to the access control system. The switch for detecting load on the knob is monitored only when the internal electronics is trying to unlock or relock the device. If there is a pre-load on the knob, the system will wait until the knob is released before attempting to unlock or relock.
While the invention has been described by reference to various specific embodiments, it should be understood that numerous changes may be made within the spirit and scope of the inventive concepts described. Accordingly, it is intended that the invention not be limited to the described embodiments, but will have full scope defined by the language of the following claims.
This Application claims the benefit of U.S. Provisional Application No. 61/536,013, filed Sep. 18, 2011.
Number | Date | Country | |
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61536013 | Sep 2011 | US |