A managing, recharging and protecting system (1) is described including: a first central processing unit, CPU (3) containing at least one managing and control application; a second central processing unit (4) operatively connected to said first central processing unit (3); at least one anti-theft device (5) designed to be wrapped around an article (10) to be protected and operatively connected to said central processing unit (4); at least one charging column (9) operatively connected to said anti-theft device (5) and designed to recharge said article (10) when connected to it.

The invention relates to a system for charging and for holding a battery-powered vehicle (20, 30). The system comprises an adapter (4) for being mounted on the vehicle (20, 30), in particular for being mounted on a cylindrical handlebar (21, 31) of a two-wheeled vehicle, the adapter (4) comprising a charging apparatus (41) that corresponds to the charging device (11) and has a receiver coil, wherein, when the fastening device is open, the receiving region extends between its longitudinal ends in the longitudinal direction X over at least 3 cm, and the transmission coil has a cross-sectional area of at least 15 cm.sup.2, wherein the fastening device, when closed, sets the mobility of the holding portion to a holding tolerance range which is set in its transverse extension and in its longitudinal extension, wherein the charging device (11) and the charging apparatus (41) can be correspondingly designed in such a way that, when the charging apparatus (41) is situated relative to the charging device (11) within a position tolerance range, this allows electrical energy to be transmitted from the charging device (11) to the charging apparatus (41) with an efficiency of more than 80%.

Methods and systems for sharing digital electronic keys (e-keys) to use a vehicle with the e-key are provided. One example method includes sending, via a first application of a first mobile device, a message to a second mobile device to initiate providing access to the vehicle via the e-key. The method includes receiving, by the first mobile device, data confirming from the second mobile device indicating receipt and creating the e-key at the second mobile device for the vehicle with a level of access that was set via the first application of the first mobile device. The data confirming receipt for the e-key is authenticated by the first mobile device. The method includes sending, by the first mobile device, verification of the e-key for use via the second mobile device. The e-key is registered with a server to enable activation of the e-key on the second mobile device. A second application of the second mobile device provides a user interface for access of the e-key for unlocking and starting the vehicle. In one example, the e-key is usable via wireless communication with the vehicle over a near field communication (NFC) connection. In one example, the first application of the first mobile device is provided with an interface to enable revocation to disable the e-key shared with a user of the second mobile device.

The present invention relates to a stopper-type charging device and a driving method thereof, wherein the stopper-type charging device includes an emergency bell unit that is provided on a main body part of a stopper for a vehicle installed on a floor of a parking lot and operates to prevent crime in a surveillance blind spot in the parking lot, a light emitting unit that guides a vehicle parked in the parking lot to be parked in a parking section for charging, and operates as a flash to illuminate a periphery of the vehicle, and a sensor unit that detects a fire by detecting a flame of the vehicle being charged.

Motor control systems and methods for micromobility transit vehicles are provided. A micromobility transit vehicle may include an electric motor configured to drive a rotation of a wheel. The electric motor may include a plurality of windings and a plurality of switching circuits. The switching circuits may be configured to selectively direct current from a power supply through the windings to generate a torque by the electric motor to drive the rotation of the wheel in response to associated control signals. The switching circuits may be configured to passively bypass the windings in response to an interruption of the control signals. Depletion of the power supply may result in the interruption of the control signals.

Techniques are disclosed for systems and methods associated with locking a micromobility transit vehicle to a stationary object. A multimodal transportation system may include a docking station including a securement point, and a micromobility transit vehicle securable to the securement point of the docking station. The micromobility transit vehicle may include a storage basket and a lock cable including a first end coupled to the storage basket and a second end. The second end of the lock cable may be securable to the securement point of the docking station to lock the micromobility transit vehicle to the docking station. The storage basket may include a pin lock. The pin lock may engage a locking pin of the lock cable to lock the micromobility transit vehicle via the lock cable.

An apparatus, including a first circuit which contains a first load which does not draw current from a first battery when not operating, and includes an electric motor of an electric vehicle or hybrid vehicle; a second circuit which contains a second load which draws current from a second battery when the first load is not operating or is non-operational; a first switch which is capable of disconnecting the first battery from the first circuit; a second switch which is capable of connecting the first battery to the first circuit; and at least one recharger which is capable of recharging the first battery and the second battery when the first load is operating. The apparatus is capable of providing electrical power to the second load when the at least one recharger ceases to operate or becomes non-operational. The first load is an eaxle.

A securing system for securing an electric bicycle to a bicycle docking frame includes a female connecting assembly mountable on the bicycle docking frame and a male connecting assembly mountable on the electric bicycle and sized to be received within a tapered recess of the female connecting assembly. When so received, first current coupling elements of the female assembly electrically interface with second current coupling elements of the male assembly, which can allow current flow therebetween to charge a battery of the electric bicycle. A bicycle rack system includes electric bicycles, bicycle docks, a charging module operable to receive electrical power from an external power source and a charging controller for adjusting the level of electrical power provided to dock-side charging modules that charge battery modules of electric bicycles docked thereto. A method for managing charging and an electric bike are also disclosed.

Techniques are disclosed for systems and methods associated with locking a micromobility transit vehicle to a stationary object. A multimodal transportation system may include a docking station including a securement point, and a micromobility transit vehicle securable to the securement point of the docking station. The micromobility transit vehicle may include a storage basket and a lock cable including a first end coupled to the storage basket and a second end. The second end of the lock cable may be securable to the securement point of the docking station to lock the micromobility transit vehicle to the docking station. The storage basket may include a pin lock. The pin lock may engage a locking pin of the lock cable to lock the micromobility transit vehicle via the lock cable.

A cable (1) for anti-theft protection, electric charging and data communication for two-wheeled electric vehicles is described, comprising: an external containment sheath (13); a spiral armor (11) designed to ensure anti-theft mechanical seal; a sheath (9) contained in the spiral armor (11); and a group (7) of conductors (3) each wrapped in an insulating element (5), this group (7) being contained in the sheath (9), each of the conductors (3) with or without connectors at its ends being designed to perform one of the following functions: electrical connection for charging a vehicle; communication link between a vehicle and another vehicle or between a vehicle and external control and management means; and alarm/anti-theft function in case of its shearing.