Described herein are systems and apparatuses for securing and locking a battery or battery enclosure to a vehicle. In general, a vehicle may include a planar body mounted to any number of wheels, tracks, wings or flotation devices. In a preferred embodiment, the security device comprises a security plate and a locking pin system is used to secure the battery to any vehicle. The security plate is positioned between the fastener heads and the battery enclosure and has an opening for the locking pin to slide through. Once the pin is inserted into security plate the pin lock secures the pin in place and prevents removal of the battery or battery enclosure from the vehicle.

A shear bolt and an axle suspension system having a shear bolt. The shear bolt may have a shear head and an enlarged head. The shear head may be configured to detach from the shear bolt. The enlarged head may have first and second protrusions that may be grasped by a tool in a manner that prevents tightening of the shear bolt.

The present invention provides an improved lug nut protection system that includes a keyed lug nut and a specialty tool for installation and removal. According to a preferred embodiment, the present invention includes a protective sleeve which slides over the wheel end of a given lug nut, and which is held in place by a retaining ring or the like. According to a further preferred embodiment, the protective sleeve preferably freely rotates and prevents common tools (i.e., pipe wrenches) from removing the lug nut thus preventing theft of the wheel/tire. According to a further preferred embodiment, the lug nut of the present invention is preferably recessed within the protective sleeve and preferably includes a keyed head which requires a specialty tool to remove the lug nut. Preferably, the specialty tool of the present invention fits inside the sleeve and over the top of the custom lug nut design.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, are described for implementing a smart security fastener. The smart security fastener includes a body configured to be installed at a property; and a head that is supported by the body. The head has circuitry that includes: a micro-processor that generates control signals; and a radio device that is coupled to the micro-processor. The radio device is operable to: i) transmit data to a property monitoring system based on the control signals, where the data indicates an installation status of the smart security fastener; and ii) receive a command from the property monitoring system that indicates authorization to uninstall the smart security fastener. The circuitry also includes a power source that powers each of the micro-processor and the radio device.

The invention relates to a spring element for a device for compensating for tolerances between a first and a second component, characterized by at least one spring arm which has two opposite end regions along its longitudinal direction, wherein at least one of the end regions has a greater distance from a longitudinal central axis of the spring element than an intermediate section of the spring arm between the end regions, and wherein at least one of the end regions forms a corner which protrudes radially outwards.

A compensating fastener assembly is configured to secure a fastener to a surface element. The compensating fastener assembly includes a compression limiter having a cylindrical main body and a flange, the cylindrical main body defining a channel and a longitudinal axis. The compensating fastener assembly further includes a spring defining a central passage. The central passage of the spring is configured to receive the main body of the compression limiter such that a first end of the spring is configured to be disposed adjacent the flange of the compression limiter.

An assembly comprising first and second structural elements having aligned holes, a fastener that occupies at least respective portions of the holes without a surrounding sleeve, and a mating part that is coupled to the fastener. The fastener comprises: a head; a circular cylindrical shank extending from the head; a mating portion comprising external projections; and a transition portion disposed between the shank and the mating portion. The transition portion comprises a tapered lead-in section that meets the shank at a shank/lead-in intersection and a radiused lead-in section that meets the tapered lead-in section. The tapered lead-in section tapers gradually in a first axial direction toward the mating portion and has a first profile that is linear and a taper angle equal to or less than 20 degrees, while the radiused lead-in section curves abruptly in the first axial direction and has a second profile that is a circular arc having a radius.

A mounting assembly unit includes a mounting element (12) to be fixed by at least one fastening bolt (30). At least one mounting element passage opening (14, 16) is provided in the mounting element (12) for the passage of the at least one fastening bolt (30). A mounting aid unit (18a, 18b) associated with at least one mounting element passage opening (14, 16) is provided at the mounting element (12). The mounting aid unit (18a, 18b) associated with the mounting element passage opening (14, 16) has a mounting aid unit passage opening (22a, 22b), which is positioned aligned with respect to the mounting element passage opening, such that an edge area (28a, 28b of the mounting aid unit (18a, 18b), which edge area surrounds the mounting aid unit passage opening (22a, 22b), is arranged overlapping the mounting element passage opening (14, 16) in some areas.

A three-piece locking fastener including an interiorly threaded intermediate component open at opposite ends. A first screw having a first exterior thread pattern rotationally inter-engages with the interior threads of the intermediate component when installed through a first selected one of the opposite ends, the first screw having a hollow shaft exhibiting a further plurality of interior threads matching a direction of the first thread pattern. A second screw has a second exterior thread pattern opposite the first pattern and, upon being installed within the other selected one of the opposite ends, rotationally inter-engages the interior threads of the first screw, so that loosening of either of the first and second screws being prevented by their counter-threaded orientation.

A captive fastener is disclosed having a longitudinal slot along the shank for receiving a hold out clip, and a pair of diametrically opposed slots for receiving a pair of push out clips. The push out clips are formed with hook shaped ends that catch and engage an edge of a wall surface to set the distance of depth of the fastener inside the wall. The hold out clip and push out clips are shaped to receded inside their respective slots in the presence of an interfering surface as the fastener passes through the wall in a first direction (insertion), but the push out clips will not recede into their slots in the second direction (withdrawal).