Systems and methods for providing secure locks having redundant access channels are disclosed. In some embodiments of the invention, the smart lock has a hardware processor, a power source, a cylinder, a button that forms a rose knob, and a rose protector. The rose knob and rose protector protect and conceal the hardware processor, the power source, and the cylinder. The rose protector forms an annular groove that slidably interlocks with the rose knob. The rose knob has a plurality of redundant access channels for receiving authentication information. The redundant access channels may include a biometric scanner for receiving biometric information, a passcode keypad for entering a token, or a wireless transceiver for receiving a token from a mobile device and transmitting a response to the mobile device. When the user cannot open the lock through the first redundant access channel, the smart lock is configured to allow access through a second access channel.

Systems and methods for providing secure locks having redundant access channels are disclosed. In some embodiments, the smart lock has a hardware processor, a power source, a cylinder, a button that forms a rose knob, and a rose protector. The rose knob and rose protector protect and conceal the hardware processor, the power source, and the cylinder. The rose protector forms an annular groove that slidabiy interlocks with the rose knob. The rose knob has a plurality of redundant access channels for receiving authentication information, The redundant access channels may include a biometric scanner for receiving biometric information, a passcode keypad for entering a token, or a wireless transceiver for receiving a token from a mobile device and transmitting a response to the mobile device. When the user cannot open the lock through the first redundant access channel, the smart lock is configured to allow access through a second access channel.

An arrangement (10) for a lock device (88a, 88b), the arrangement (10) comprising an input member (12, 106); a coupling member (26) movable between an uncoupled position (34) and a coupled position (80); an electromechanical actuator (28) comprising an actuating member (42) linearly movable between an uncoupling actuating position (44) and a coupling actuating position (78); and a torsion spring (30) having a first leg (62) and a second leg (64) movable away from each other against a deformation of the torsion spring (30), wherein the actuating member (42) is arranged to engage the first leg (62) and the second leg (64) is arranged to engage the coupling member (26) when the coupling member (26) is in the uncoupled position (34) and the actuating member (42) moves from the uncoupling actuating position (44) to the coupling actuating position (78). A lock device (88a, 88b) comprising an arrangement (10) is also provided.

The invention concerns a locking mechanism (10) comprising an indoor mechanical actuation lever (11), an outdoor mechanical actuation lever (12) and a lock clutch (13), each mechanical actuation lever being configured to switch between a closed configuration and an open configuration, wherein the lock clutch (13) is configured to take at least three positions: a first position where the lock clutch is disengaged from the indoor mechanical actuation lever and outdoor mechanical actuation lever, a second position where the lock clutch is engaged with the indoor mechanical actuation lever and outdoor mechanical actuation lever, a third position where the lock clutch is engaged with the indoor mechanical actuation lever and disengaged from the outdoor mechanical actuation lever.

The invention concerns a locking mechanism (10) comprising an indoor mechanical actuation lever (11), an outdoor mechanical actuation lever (12) and a lock clutch (13), each mechanical actuation lever being configured to switch between a closed configuration and an open configuration, wherein the lock clutch (13) is configured to take at least three positions: a first position where the lock clutch is disengaged from the indoor mechanical actuation lever and outdoor mechanical actuation lever, a second position where the lock clutch is engaged with the indoor mechanical actuation lever and outdoor mechanical actuation lever, a third position where the lock clutch is engaged with the indoor mechanical actuation lever and disengaged from the outdoor mechanical actuation lever.

Systems and methods for providing secure locks having redundant access channels are disclosed. In some embodiments of the invention, the smart lock has a hardware processor, a power source, a cylinder, a button that forms a rose knob, and a rose protector. The rose knob and rose protector protect and conceal the hardware processor, the power source, and the cylinder. The rose protector forms an annular groove that slidably interlocks with the rose knob. The rose knob has a plurality of redundant access channels for receiving authentication information. The redundant access channels may include a biometric scanner for receiving biometric information, a passcode keypad for entering a token, or a wireless transceiver for receiving a token from a mobile device and transmitting a response to the mobile device. When the user cannot open the lock through the first redundant access channel, the smart lock is configured to allow access through a second access channel.

Systems and methods for providing secure locks having redundant access channels are disclosed. In some embodiments of the invention, the smart lock has a hardware processor, a power source, a cylinder, a button that forms a rose knob, and a rose protector. The rose knob and rose protector protect and conceal the hardware processor, the power source, and the cylinder. The rose protector forms an annular groove that slidably interlocks with the rose knob. The rose knob has a plurality of redundant access channels for receiving authentication information. The redundant access channels may include a biometric scanner for receiving biometric information, a passcode keypad for entering a token, or a wireless transceiver for receiving a token from a mobile device and transmitting a response to the mobile device. When the user cannot open the lock through the first redundant access channel, the smart lock is configured to allow access through a second access channel.

An actuating assembly of a locking system (200) to operate a displaceable component of a latching system (210), includes: (i) a first member (24) which is connected or connectable to the displaceable component of the latching system (210); (ii) a second member (26), the first and second members (24, 26) being disconnectably connectable to each other, with the first and second members (24, 26) being in an inoperative configuration when they are disconnected from each other such that the second member (26) is displaceable independently of the first member (24), and the first and second members (24, 26) being in an operative configuration when they are connected to each other such that displacement of the second member (26) causes the first member (24) to be displaced; (iii) a first actuating sub-assembly (46) including a first key receiver (230) for receiving a non-mechanical first key in the form of a predetermined electromagnetic signal transmitted via a cellular telecommunications network from the communications facility (224) of a monitoring facility (227) to an electronic controller (228); (iv) a second actuating sub-assembly (52) which is operable by a second key (226), the second actuating sub-assembly (52) being operably connected to the second member (26) and being configured, when actuated by the second key (226), to cause the second member (26) to be displaced, thereby to cause the first member (24) to be displaced when the first and second members (24, 26) are in their operative configuration; and (v) a timer for determining the time from receipt of a first key by the first actuating sub-assembly (46), wherein the first actuating subassembly (46) is configured, upon: (i) receipt of the first key, to cause the first and second members (24, 26) to assume their operative configuration; and (ii) elapse of a preset time stored in a storage means (236) measured by the timer from receipt of a first key by the first actuating sub-assembly (46), to cause the first and second members (24, 26) to assume their inoperative configuration.

An actuating assembly of a locking system (200) to operate a displaceable component of a latching system (210), includes: (i) a first member (24) which is connected or connectable to the displaceable component of the latching system (210); (ii) a second member (26), the first and second members (24, 26) being disconnectably connectable to each other, with the first and second members (24, 26) being in an inoperative configuration when they are disconnected from each other such that the second member (26) is displaceable independently of the first member (24), and the first and second members (24, 26) being in an operative configuration when they are connected to each other such that displacement of the second member (26) causes the first member (24) to be displaced; (iii) a first actuating sub-assembly (46) including a first key receiver (230) for receiving a non-mechanical first key in the form of a predetermined electromagnetic signal transmitted via a cellular telecommunications network from the communications facility (224) of a monitoring facility (227) to an electronic controller (228); (iv) a second actuating sub-assembly (52) which is operable by a second key (226), the second actuating sub-assembly (52) being operably connected to the second member (26) and being configured, when actuated by the second key (226), to cause the second member (26) to be displaced, thereby to cause the first member (24) to be displaced when the first and second members (24, 26) are in their operative configuration; and (v) a timer for determining the time from receipt of a first key by the first actuating sub-assembly (46), wherein the first actuating subassembly (46) is configured, upon: (i) receipt of the first key, to cause the first and second members (24, 26) to assume their operative configuration; and (ii) elapse of a preset time stored in a storage means (236) measured by the timer from receipt of a first key by the first actuating sub-assembly (46), to cause the first and second members (24, 26) to assume their inoperative configuration.

Systems and methods for providing secure locks having redundant access channels are disclosed. In some embodiments of the invention, the smart lock has a hardware processor, a power source, a cylinder, a button that forms a rose knob, and a rose protector. The rose knob and rose protector protect and conceal the hardware processor, the power source, and the cylinder. The rose protector forms an annular groove that slidably interlocks with the rose knob. The rose knob has a plurality of redundant access channels for receiving authentication information. The redundant access channels may include a biometric scanner for receiving biometric information, a passcode keypad for entering a token, or a wireless transceiver for receiving a token from a mobile device and transmitting a response to the mobile device. When the user cannot open the lock through the first redundant access channel, the smart lock is configured to allow access through a second access channel.