A locking and release system of a lock fitted on a vehicle comprising: a mechanical lock (10, 70) which is fixed on a door of a vehicle; an electronic circuit (11) associated with said lock (10, 70); said electronic circuit (11) comprises a Bluetooth communication device (13); an Internet communication device (14); a GPS localization device (15); said system further comprises: a cloud (30) containing the data for the management of said system; a management centre (35) of said system; said management centre (35) is adapted to communicate with said cloud (30); a smartphone (21); said smartphone (21) comprises a Bluetooth communication device (22); an HTTPS communication device (23); and a GPS localization device (24); said electronic circuit (11) and said smartphone (21) are adapted to communicate with said cloud (30); said smartphone (21) is adapted to communicate with said electronic circuit (11); said lock (10, 70) opens if the following conditions are met: the GPS position of the lock (10, 70) coincides with the delivery position; the GPS position of the smartphone (21) coincides with the delivery position; said smartphone (21) is recognized by the system; said lock comprises coupling means (56, 74), located on a first door adapted to close against closing means (59, 71) located on a second door and locking means (60, 78) adapted to lock said coupling means (56, 74) in the closed position.

An illustrative example embodiment of a locking device includes a lock that selectively allows access to an area when the lock is unlocked. A processor is configured to control whether the lock is locked or unlocked. A transceiver is configured to communicate with a communication hub that is remote from the locking device. The processor is configured to cause the transceiver to provide an indication to the communication hub when the lock has been unlocked. The indication includes an instruction that the communication hub should begin monitoring a condition of at least one preselected item within the area.

An electromechanical lock assembly (1) comprising a lock body (13), a lock core (21) located at least partially within the lock body (13) and selectively rotatable with respect to the lock body (13), the lock core (21) including a key receptacle (23), a bolt operating member rotationally secured to the lock core (21) and configured to move a lock bolt of a lock (3) for locking and unlocking said lock (3), and a programmable key (12), wherein said electromechanical lock assembly is configured to be powered upon insertion of the programmable key (12) in said key receptacle (23). A position sensing device (27) is arranged to transmit position data to said programmable key (12).

Disclosed is an invention that relates to a breakage prevention type card key. A breakage prevention type card key of the present invention includes: a substrate part installed inside a case part, a key accommodation part connected to the substrate part and having a groove into which an auxiliary key part is inserted, a locking part located inside the key accommodation part and elastically pressurizing a side surface of the auxiliary key part stored in the key accommodation part to restrain the movement of the auxiliary key part, and a reinforcement part extended from key accommodation part and coupled to the case part and augmenting the rigidity of the case part located on both sides of the entrance of the key accommodation part.

A compensating element having first and second modules is disclosed. A locking mechanism which can be switched between a first and a second operating state is provided. The first module is connected firmly to the second module in the first operating state. The first operating state defines a zero position between the first and the second module. The first and the second module are connected to one another in the second operating state by a spring mechanism in such a way that they are movable relative to one another. The compensating element has a midaxis, and the first and the second module are arranged at least partially next to one another in the direction of the midaxis. A measuring system is also disclosed with which the relative position between the first and the second module can be measured. The first or second module includes an externally visible luminous surface. A luminous state of the luminous surface is dependent on the relative position measured by the measuring system.

A device for accommodating a component in an interior space has a housing comprising a housing wall delimiting the interior space of the housing, and a passage portion in the wall. The component comprises a sensing element with an actuating portion, and a holding portion mechanically connected to said actuating portion and has at least one latching hook with a latching lug. The component has a holder with a latching edge. When the component is accommodated in the interior space, the actuating portion, in a first state, is arranged in the passage portion, and, to reach a second state with the actuating portion in the interior space, is displaceable into the interior space so the latching lug of the latching hook engages over the latching edge. The latching connection so created prevents the actuating portion from being displaced in the direction of the passage portion, and enables damage-free removal.

The present invention relates to a smart key for a vehicle including a substrate part on which components are mounted, a key accommodation part formed on the substrate part and into which an auxiliary key part is inserted, a reinforcement part coupled to the substrate part and augmenting rigidity, and a case part covering the substrate part, the key accommodation part, and the reinforcement part to augment the rigidity thereof.

A self-venting device includes a first component having an interior, a second component coupled to the first component so as to close the interior, and seal structure engaged between the first and second components in a sealed state so as to seal the interior from external agents. The seal structure includes a plurality of seal members, each having a resilient seal tip extending therefrom. The seal tips are constructed and arranged such that 1) when pressure inside the interior is equal to pressure outside of the device, the seal tips are compressed between the first and second components in the sealed state, and 2) when pressure in the interior is greater than the pressure outside of the device causing the second component to move away from the first component, the seal tips move to an unsealed state, permitting air to exit from the interior.

An electronic key having the following features. The electronic key has a key housing and a switch housing in the key housing. The switch housing has an inherently rigid frame having at least one first breakout, and a flexibly deformable membrane which is arranged on the frame in order to close the at least one breakout and to forward a force having effect from the outside on the membrane in the region of the breakout to an electrical switch element arranged within the frame. An electronic key having the required amount of stiffness is thus created, in which sensitive electronic components located therein are also protected from environmental influences. If the deformable membrane is not only used for button-related functions, but also for forming an ejection section for an emergency key or as a rattle protection for the emergency key, a multifunctional switch housing can thus be created simply.

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.