A wheel locking device comprising a number of interlocking components that are adapted to receive a wheel (or a wheeled apparatus), and said components can be adjusted to accommodate a variety of wheels of different diameters. The wheel locking device further comprises a rotatable and adjustable bar that is utilized to secure the wheel in place. In further embodiments, the device comprises a lock receiving bore which is adapted to receive a lock.

A guarded track lock includes a support plate having a planar anterior face, a finger protruding outwardly away from the planar anterior face, and a bolt protruding outwardly away from the planar anterior face and registered parallel to the finger. A face plate has a plurality of statically coupled portions angularly offset from a central axis of the bolt, wherein one of the portions has an aperture configured to receive the bolt therethrough. A protective cover is removably engaged with the face plate and supported against the one portion, a nut affixed to the bolt and seated within the protective cover, and a locking member releasably connected to the bolt and seated within the protective cover. The bolt is configured to fit through the sprocket of the existing power-operated machinery, thereby providing the new and useful result of prohibiting operation of the track in forwarded and reward directions.

A guarded track lock includes a support plate having a planar anterior face, a finger protruding outwardly away from the planar anterior face, and a bolt protruding outwardly away from the planar anterior face and registered parallel to the finger. A face plate has a plurality of statically coupled portions angularly offset from a central axis of the bolt, wherein one of the portions has an aperture configured to receive the bolt therethrough. A protective cover is removably engaged with the face plate and supported against the one portion, a nut affixed to the bolt and seated within the protective cover, and a locking member releasably connected to the bolt and seated within the protective cover. The bolt is configured to fit through the sprocket of the existing power-operated machinery, thereby providing the new and useful result of prohibiting operation of the track in forwarded and reward directions.

A vehicle locking boot includes a horizontal support arm and a first vertical support arm extending from the horizontal support arm. The first vertical support arm includes a front engagement protrusion. A receiving sleeve extends from the horizontal support arm at a base of the first vertical support arm. A horizontal extension portion is coupled to the horizontal support arm. A second vertical support arm extends from the horizontal extension portion. The second vertical support arm includes a rear engagement protrusion extending therefrom. The front engagement protrusion faces the rear engagement protrusion. A keypad is disposed on the first engagement portion to lock and unlock the horizontal extension portion. A lug nut blocking plate is coupled to the first vertical support arm. A global positioning system (GPS) housing is positioned at an upper portion of the first vertical support arm.

A vehicle locking boot includes a horizontal support arm and a first vertical support arm extending from the horizontal support arm. The first vertical support arm includes a front engagement protrusion. A receiving sleeve extends from the horizontal support arm at a base of the first vertical support arm. A horizontal extension portion is coupled to the horizontal support arm. A second vertical support arm extends from the horizontal extension portion. The second vertical support arm includes a rear engagement protrusion extending therefrom. The front engagement protrusion faces the rear engagement protrusion. A keypad is disposed on the first engagement portion to lock and unlock the horizontal extension portion. A lug nut blocking plate is coupled to the first vertical support arm. A global positioning system (GPS) housing is positioned at an upper portion of the first vertical support arm.

A secure locking hub system for locking a wheel hub of a vehicle to an axle is provided. The system has a locking ring that may be manually inserted and removed by a user to switch the system between locked and unlocked configurations. When in the locked configuration, the hub is in a rotationally fixed position relative to the axle on which the hub is mounted. With the hub locked to the axle, the wheel will not rotate and the vehicle thus cannot be moved. The system additionally has a security lock that prevents any unauthorized individual from removing the locking ring, thereby preventing theft of the vehicle.

A secure locking hub system for locking a wheel hub of a vehicle to an axle is provided. The system has a locking ring that may be manually inserted and removed by a user to switch the system between locked and unlocked configurations. When in the locked configuration, the hub is in a rotationally fixed position relative to the axle on which the hub is mounted. With the hub locked to the axle, the wheel will not rotate and the vehicle thus cannot be moved. The system additionally has a security lock that prevents any unauthorized individual from removing the locking ring, thereby preventing theft of the vehicle.

A vehicle includes a first sensor that senses a state of the vehicle and a second sensor that senses outside of the vehicle. A computing device is configured to receive signals from the sensors and to control rotating and turning of the wheels. While the vehicle is parked, the computing device determines according to a signal received from the sensors, that a condition is satisfied. The condition may be associated with a particular wheel. Based on determining that the condition is satisfied, and while the vehicle remains parked, the computing device initiates automatically rotating or turning the particular wheel associated with the condition.

A vehicle includes a first sensor that senses a state of the vehicle and a second sensor that senses outside of the vehicle. A computing device is configured to receive signals from the sensors and to control rotating and turning of the wheels. While the vehicle is parked, the computing device determines according to a signal received from the sensors, that a condition is satisfied. The condition may be associated with a particular wheel. Based on determining that the condition is satisfied, and while the vehicle remains parked, the computing device initiates automatically rotating or turning the particular wheel associated with the condition.

Secure access to a vehicle is described, in which one or more biometric identifiers of a user may be utilized to enable the vehicle. The user may not operate the vehicle without satisfying security measures based on his/her biometric identifier generated from various biological traits. In some embodiments, an artificial engine and/or algorithm may be combined to facilitate the authentication process to determine whether the user is authorized to use the vehicle. The secure access features may also manage a list of biometric identifiers of the authorized users. In some instances, the secure access features may be temporarily disabled. Further, individual parts of the vehicle may be associated with a unique identifier of the vehicle (which may include a vehicle identification number), and/or may be configured to transmit their geological locations determined by a global positioning system (GPS).