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.

The present invention relates to an electromechanical lock assembly (1) comprising a lock body (15), a lock core (17), a lock bolt operating member (19), and an electronic access control device. The electromechanical lock assembly further comprises an annular element (27) which is rotatably and axially displaceably mounted on said lock core (17), a coupling device (25) arranged to communicate with said electronic access control device and, upon the insertion of an appropriate key (65) in a key receptacle (37) of the lock core (17), rotationally lock the annular element (27) to the lock core (17), thereby enabling rotation of the lock core (17) in a first direction and thereby enabling unlocking of a lock (3) with said appropriate key (65), and a blocking arrangement (63) arranged to prevent unauthorized unlocking of said lock (3).

Disclosed is an invention related to a card type smart key. The disclosed card type smart key includes a key main body part having a circuit substrate installed thereinside, a battery cover part having a battery mounted thereon and inserted into an insertion part formed in the key main body part, and a contact part installed in the key main body part so as to be in contact with the battery and having elastic restoration force in the battery side direction.

A touchless motion sensor system for performing directional motion detection includes first and second touchless motion sensors. First and second sensing units are coupled to the first and second touchless motion sensors each having a sensing unit disable input, a sensing unit disable output, a sensing unit to sensing unit motion detected output, and motion logic. The first sensing unit disable output is coupled to the second sensing unit disable input, and the second sensing unit disable output is coupled to the first sensing unit disable input.

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 plurality of operator controls can, in an operation mode, operate a machine, and, in a validation mode, be disabled to operate the machine and selectable to provide inputs for a candidate key. A computing device can initialize the validation mode, including initializing the candidate key and, according to a number base, and a maximum storage length, of a stored key, an input multiplier; receive a plurality of inputs to the operator controls in the validation mode; determine respective numeric values of the inputs; add the candidate key to a product of the multiplier and the numeric value of a first input to update the candidate key; for each of one or more second inputs to the operator controls after the first input to the operator controls, determine whether the candidate key matches a stored key; and upon determining that the candidate key matches the stored key, output an authorization.

A system according to an embodiment includes electronic lock and key of which the electronic lock can be installed on a portal such as a door. The electronic lock is capable of contact-less authentication of the electronic key carried in person by a user, and also determines the open/close condition of the door panel with respect to the door frame. Being an add-on, there is no need to replace or modify the existing mechanical lock at the door. The electronic key does not require any batteries to operate, being powered by the electronic lock through wireless transfer of power through the door panel. After a successful authentication of the electronic key, the electronic lock clears the user to open the door. An attempted illegal entry by force or using duplicate key of the mechanical lock without electronic authentication is considered intrusion. Once an intrusion is detected, the system generates an alarm at the premises as well informs multiple mobile devices (e.g., cell phone) anywhere in the world through a wireless network. The electronic lock can be powered by a battery or AC source depending on the installation scenario.

An electronic access system and method utilizes a modular latch system and method. The modular latch system and method include a reader module and latch module. The reader module includes a user interface with one or more readers or devices for receiving input from a user, and sending the input to a controller. The latch module is configured for mounting to a closure that provides access to the secure area. The latch module can be operated in a stand-alone mode while detached from the reader module. Alternatively, the latch module can be releasably engaged to the reader module and operated in an assembled mode. The modular system and method allow for engagement of the reader module to the latch module, disengagement of the reader module from the latch module, and engagement of an alternate reader module to the latch module for retrofitting the reader module with the alternate reader module.

A lock, in particular for an electric bicycle, includes a locking mechanism that has a latch that is movable between a latched position, which is provided for securing a counter-piece movable relative to the locking mechanism, and an unlatched position provided for releasing the counter-piece. The lock includes a blocking device, including a blocking element that is adjustable between a blocking position, in which the latch is blocked in its latched position, and a release position in which the latch is movable into its unlatched position, and a reception unit for receiving a release signal by which the adjustment of the blocking element into the release position can be brought about. A locking system may include at least one such lock.

In some aspects, an electronic lock box may include a heated section, a cooled section, a non-temperature controlled section, and a processor. The processor may receive, from a server, an indication of an electronic order. The processor may identify a code associated with an item. The processor may determine, from the code, a tracking number associated with the item and the description of the item. The processor may determine that the tracking number associated with the item corresponds to a tracking number associated with the electronic order and that a current date corresponds to an expected delivery date. The processor may provide an instruction to unlock the heated section, the cooled section, or the non-temperature controlled section to hold the item based on the description of the item. The processor may maintain an environmental status of sensors (e.g., weight, volume, temperature, operations, and/or location) within the electronic lock box.