A helmet mount system for attaching a device to a helmet comprises a threaded interface assembly having an outer portion and a threaded insert received within a cavity formed in the outer portion. The outer portion has an inward facing surface configured to receive an adhesive layer for coupling the inward facing surface to a surface of the helmet. In a further aspect, a ballistic helmet having the helmet mount system herein is provided, wherein the helmet mount system does not penetrate a ballistic layer of the ballistic shell.

A mounting device having a mounting assembly for mounting a pair of goggles to a helmet is provided. The mounting assembly is configured to provide at least three degrees of freedom of movement using one or more actuation mechanisms for locking and unlocking a position of the mounting device. The number of actuation mechanisms is less than a number of degrees of freedom. In some aspects, the number of actuation mechanisms is one. A rotation base connects the mounting assembly to the helmet, and a goggle linkage connects the mounting assembly to the goggles. Various single actuation mechanisms, including a sliding mechanism, a friction-based wire/brake mechanism, and a floating friction brake mechanism, are provided.

A mounting device having a mounting assembly for mounting a pair of goggles to a helmet is provided. The mounting assembly is configured to provide at least three degrees of freedom of movement using one or more actuation mechanisms for locking and unlocking a position of the mounting device. The number of actuation mechanisms is less than a number of degrees of freedom. In some aspects, the number of actuation mechanisms is one. A rotation base connects the mounting assembly to the helmet, and a goggle linkage connects the mounting assembly to the goggles. Various single actuation mechanisms, including a sliding mechanism, a friction-based wire/brake mechanism, and a floating friction brake mechanism, are provided.

This disclosure describes a rotational coupling mechanism for releasably coupling a device to a mounting platform. In one example, a user may nest a device within the mounting platform and perform a single rotation of the nested device to toggle between a locked position and an unlocked position. The user may continue the single rotation of the nested device, in the same clockwise or anticlockwise direction, to toggle the device from the unlocked position and back to the locked position. In a locked position, the device is restricted from translation relative to the mounting platform, however, the device may continue to rotate in a clockwise or counterclockwise direction to toggle between a locked and unlocked position. In an unlocked position, the device may disengage freely from the mounting platform and is thus subsequently free to move in any translational direction or about any rotational axis.

A water-meter extension pole is an apparatus that positions a smart device beside a water meter in order to safely and accurately capture a water meter reading. The apparatus includes a length-adjustable pole, a first holder, a second holder, and a handle. The length-adjustable pole upholds and positions the first holder and the second holder a desired distance from the handle. The first holder is preferably a spring-loaded clamp that secures a water-meter. The second holder secures a smart device, preferably with a camera, beside the first holder. The handle provides a grip for a user with the length-adjustable pole. The smart device is remotely operated as the apparatus further includes a controller housing, a microcontroller, a wireless communication device, a power source, a power button, and a controller button. The controller housing contains the microcontroller, the wireless communication device, and the power source, preferably beside the handle.

Disclosed is an electronic gimbal with camera and mounting configuration. The gimbal can include an inertial measurement unit which can sense the orientation of the camera and three electronic motors which can manipulate the orientation of the camera. The gimbal can be removably coupled to a variety of mount platforms, such as an aerial vehicle, a handheld grip, or a rotating platform. Moreover, a camera can be removably coupled to the gimbal and can be held in a removable camera frame. Also disclosed is a system for allowing the platform, to which the gimbal is mounted, to control settings of the camera or to trigger actions on the camera, such as taking a picture, or initiating the recording of a video. The gimbal can also provide a connection between the camera and the mount platform, such that the mount platform receives images and video content from the camera.

Disclosed is an electronic gimbal with camera and mounting configuration. The gimbal can include an inertial measurement unit which can sense the orientation of the camera and three electronic motors which can manipulate the orientation of the camera. The gimbal can be removably coupled to a variety of mount platforms, such as an aerial vehicle, a handheld grip, or a rotating platform. Moreover, a camera can be removably coupled to the gimbal and can be held in a removable camera frame. Also disclosed is a system for allowing the platform, to which the gimbal is mounted, to control settings of the camera or to trigger actions on the camera, such as taking a picture, or initiating the recording of a video. The gimbal can also provide a connection between the camera and the mount platform, such that the mount platform receives images and video content from the camera.

A magnet mount assembly is provided for quickly mounting and releasing the portable electronic device to various objects, including stands, clamps and/or holders (i.e., support mount) to support the portable electronic device in elevated positions at a variety of angles. The magnet mount assembly may attach to the back of the temperature control device or electronics case or to the back of the portable devices by, for example, connecting to the universal mount. The mount may further include pong pins or other electrical connectors for supplying power and/or data to the cooling mount and/portable electronic device when the magnet mount assembly.

The disclosed flexible facial interface assemblies for head-mounted display systems may include a rigid support frame element and a flexible facial interface frame element. The rigid support frame element may be shaped and configured to physically support a display of a head-mounted display system in front of a user's eyes when the facial interface assembly is worn by the user. The flexible facial interface frame element may be configured to flex to conform to the user's facial features when the facial interface assembly is worn by the user. An outer periphery of the flexible facial interface frame element may be independently movable relative to an outer periphery of the rigid support frame element. Various other systems and methods are also disclosed.

A load-stabilizing apparatus includes a load-connecting member configured to carry a load, a parallelogram mechanism connected to the load-connecting member, and a stabilizing motor drivingly connected to the parallelogram mechanism. The stabilizing motor is configured to drive the parallelogram mechanism to deform, such that the parallelogram mechanism drives the load-connecting member to move.