Patent Grant
8610535
The present patent application relates to a door locking system and more particularly to a door locking system that includes an electrically lockable swivel lever actuating mechanism for cabinet.
A conventional swivel lever actuating mechanism mounted on a door frame simply locks and unlocks the cabinet, without the detection of whether the door frame is open or closed in a cabinet. This is a not convenience for many applications.
It is desired to have a door locking system mounted on door frame in a cabinet that includes a swivel level actuating mechanism of locking and unlock the door frame, and built-in sensor(s) to detect the door frame status of whether the door frame is open or closed in a cabinet.
The present patent application is directed to a door locking system configured to lock and unlock a door frame of a cabinet. In one aspect, the door locking system includes a handle rod; a digital or mechanical door sensor configured to detect whether the door frame of the cabinet is open or closed; and a latch configured to lock the handle rod, the latch being connected to and controlled by a lock mechanism. The lock mechanism includes a mechanical module and an electromechanical module. The mechanical module is configured to actuate the latch to lock and unlock the handle rod, and configured to grant the electromechanical module control over the latch to lock and unlock the handle rod.
The mechanical module may include a mechanical key lock with a dish, and the electromechanical module may include a motor or a solenoid, and is controlled by an electrical signal.
The electromechanical module may be connected to and controlled by a handle board and a RFID (radio frequency identification) board, the RFID board being configured to identify a RFID card or tag placed nearby. The handle board may be further connected to a sensor board for detecting temperature, humidity, and vibration. The handle board may be further connected to a status board for detecting the status of the mechanical module. The handle board may be further connected to a communication board for communicating with a data network either by wire or wirelessly. The RFID board may include a biometric information reader, the biometric information reader being configured to acquire biometric authentication data from a user and transmit the data to the handle board and the electromechanical module.
The door locking system may further include a main board and a network board. The communication board may be connected to the main board and the main board may be connected to a computer network through the network board.
The door locking system may further include a multi-device board. The multi-device board may be configured to connect a plurality of sensors for monitoring the operation of the door locking system.
In another aspect, the present patent application provides a door locking system including a plurality of door locks; a main board connected to the plurality of door locks; a network board connected to the main board; and a multi-device board connected to the network board. Each door lock includes a handle rod and a latch configured to lock the handle rod. The latch is connected to and controlled by a lock mechanism. The lock mechanism includes a mechanical module and an electromechanical module, the mechanical module being configured to actuate the latch to lock and unlock the handle rod, and configured to grant the electromechanical module control over the latch to lock and unlock the handle rod. The main board is connected to a computer network through the network board. The multi-device board is configured to connect a plurality of sensors for monitoring the operation of the door locking system and the environment nearby.
The handle board may be further connected to a communication board for communicating with a data network either by wire or wirelessly, and the communication board may be connected to the main board.
The main board may include a plurality of displays, the displays being configured to show the temperature or humidity data acquired from the door locking system.
In yet another aspect, the present patent application provides a door locking system including a plurality of door locks; a plurality of main boards each connected to the plurality of door locks; a plurality of network boards each connected to one of the main boards; and a plurality of multi-device boards each connected to one of the network boards. Each door lock includes a handle rod and a latch configured to lock the handle rod, the latch being connected to and controlled by a lock mechanism, the lock mechanism including a mechanical module and an electromechanical module. The mechanical module is configured to actuate the latch to lock and unlock the handle rod, and configured to grant the electromechanical module control over the latch to lock and unlock the handle rod. All the network boards are connected with each other one by one as a chain and to a computer network. Each multi-device board is configured to connect a plurality of sensors for monitoring the operation of the door locking system and the environment nearby.
Reference will now be made in detail to a preferred embodiment of the door locking system disclosed in the present patent application, examples of which are also provided in the following description. Exemplary embodiments of the door locking system disclosed in the present patent application are described in detail, although it will be apparent to those skilled in the relevant art that some features that are not particularly important to an understanding of the door locking system may not be shown for the sake of clarity.
Furthermore, it should be understood that the door locking system disclosed in the present patent application is not limited to the precise embodiments described below and that various changes and modifications thereof may be effected by one skilled in the art without departing from the spirit or scope of the protection. For example, elements and/or features of different illustrative embodiments may be combined with each other and/or substituted for each other within the scope of this disclosure.
The electromechanical module includes an electromechanical device 106 and a gear 105. The electromechanical device 106 includes a motor to spin the gear 105. The gear 105 has a lock position to lock the handle rod 21 and unlock position to unlock the handle rod 21. The electromechanical device 106, which is controlled by an electrical signal, may also include a solenoid. The mechanical module includes a mechanical key lock 101 with a dish 102. The latch 103 has a lock position to lock the handle rod 21 and an unlock position to unlock the handle rod 21.
The mechanical module has three types of control to the latch 103. The control types are selected by a correct key turning the dish 102 of the mechanical key lock 101 to three different positions. The three different positions are as follows:
1) a position to lock the handle rod 21 through the latch 103 in a lock position;
2) a position to unlock the handle rod 21 through the latch 103 in an unlock position, while the electromechanical module cannot control the handle rod 21; and
3) a position to unlock the handle rod 21 through the latch 103 in an unlock position, while the electromechanical module can further lock and unlock the handle rod 21 through latch 103. More particularly, the electromechanical module can lock and unlock the handle rod 21 by spinning the gear 105 with regard to the latch 103 to lock and unlock position.
It is noted that the RFID board may include one or a plurality of biometric information readers. The biometric information reader is configured to acquire biometric authentication data from a user and transmit the data to the handle board 50 and the electromechanical module.
The handle board 50 connected to a sensor board 52, where the sensor board 52 is connected to different sensors to detect including but not limited to temperature, humidity, water leak, vibration, and door status and/or position.
The handle board 50 may be further connected to a sensor board 52 to detect the temperature, humidity, water, vibration and door status and/or position. The sensor board 52 may include a tact switch, an optical sensor, and/or a magnetic sensor.
The handle board 50 may be further connected to a status board 104 to detect whether the mechanical module is in a position to lock the door frame, a position to unlock the door frame, or a position to unlock the door frame and let the electromechanical module control the locking status of the door frame, i.e. a position to grant the electromechanical module control over the latch 103 to lock and unlock the handle rod 21.
The handle board 50 may be further connected to a communication board 53 that is configured to communicate with a data network either by wire or wirelessly. The type of the communication includes but is not limited to serial, TCP/IP, I2C or 2.4G wireless communication. In this embodiment, an optional battery module 80 may be configured to supply the power to the door lock system.
The main board 200 has multiple temperature displays or temperature and humidity displays 201. The display 201 shows the temperature or temperature and humidity data acquired from the door locking systems 10.
The main board 200 and a multi-device board 400 can be further connected to a computer network through a network board 300. The network board 300 has a link port 301 to communicate with the computer network. The link port 301 can be connected to the wireless module 303 enabling the network board 300 to be wirelessly connected to the computer network.
The network board 300 has by-pass function on the link port 301 and out port 302. The data can pass through the link port 301 and out port 302 automatically even during a power failure.
The multi-device board 400 is configured to control the remote monitoring power distribution unit 401. The remote monitoring power distribution unit 401 is configured to monitor the individual socket and whole power distribution unit status, including but not limited to kilowatt per hour, power on, power off, voltage, ampere loading, temperature, humidity, vibration, noise level and ventilation.
The multi-device board 400 is configured to control the remote monitoring and switched power distribution unit 402, which can monitor and control the individual socket and whole power distribution unit status, including but not limited to kilowatt per hour, power on, power off, voltage, Ampere loading, temperature, humidity, vibration and ventilation.
The multi-device board 400 is configured to control the remote monitoring fan unit 403, which is configured to monitor the individual fan and whole fan unit status, including but not limited to fan on, fan off, fan speed, voltage, Ampere loading, temperature, humidity, vibration, noise level and ventilation.
The multi-device board 400 is configured to control the remote monitoring and switched fan unit 404, which is configured to control and monitor the individual fan and whole fan unit status, including but not limited to fan on, fan off, fan speed, voltage, Ampere loading, temperature, humidity, vibration, noise level and ventilation.
The multi-device board 400 is configured to monitor the nearby temperature by the temperature sensor 405, and also the nearby humidity by the humidity sensor 406.
The multi-device board 400 is configured to monitor the presence of water nearby by the water sensor 407, and also the vibration by the vibration sensor 408.
The multi-device board 400 is configured to watch and capture nearby environment by the camera 409.
In this embodiment, the door locking system 10 may apply different types of RFID sensors to detect different RFID cards or tags. One main board 200 may control multiple door locking systems 10. The door locking system may also support wireless data communication with the main board 200.
The door locking system 10 is configured to support a DC motor to drive the physical lock. The door locking system may support mini USB (5V) plug-in for emergency power to unlock the door by authorized card access. The door locking system 10 may include either a digital door senor or a mechanical door sensor to detect whether the door frame is open or closed in a cabinet.
The door locking system is configured to support a low cost I2C temperature sensor connected to the handle, and transmit the temperature reading to the main board. The temperature range is from −32 to ˜+99.9° C. (−27.22˜+211.82° F.), with +/−1 degree accuracy.
The door locking system 10 is configured to send the door sensor status to the main board regarding whether the door frame is open or closed in a cabinet. The status includes card access status (when the handle is locked only authorized card is accepted to unlock the handle), physical key unlock status (the handle is unlocked) and physical key lock status (handle is locked and only physical key can unlock the handle).
The door locking system 10 includes a plurality of LED indicators. A first LED indicator indicates a power-on and normal status, and a second LED indicator indicates an authorized card access. A third LED indicator indicates unauthorized card detection.
The door locking system is configured to support different audio outputs, for example, include but are not limited to authorized card detection, unauthorized card detection and/or an alarm status. The door locking system may further support battery box connection (2-pin), in case the user can't provide a DC power in the cabinet as a power input.
In the above embodiments, although RFID is disclosed as an example, it should be noted that other types of wireless identification measures may be used in the door locking system.
While the present patent application has been shown and described with particular references to a number of embodiments thereof, it should be noted that various other changes or modifications may be made without departing from the scope of the present invention.
This application claims the benefit of U.S. Provisional Application No. 61/324,787, filed on Apr. 16, 2010; the contents of which is hereby incorporated by reference.
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