A cable holder prevents fraying or tangling of cables configured to physically and electrically connect to one or more devices, such as patient monitoring devices. The cable holder can be configured to: (i) detachably secure the one or more cables, and (ii) be detachably secured to a support structure. The cable holder may include a first surface in which an aperture configured to receive a cable is defined, and a second surface on which a connector configured to removably interconnect with a connector of another cable holder is defined.

Camera mounting assemblies and mounting plates. A mounting plate includes a body. The body includes a center portion. The body further includes an extension member extending away from the center portion in a coplanar direction. The body further includes a first mounting hole located on the extension member. The first mounting hole is configured to receive a first attachment. The body further includes a second mounting hole. The second mounting hole is located on the center portion and is configured to receive a second attachment, the second attachment being different than the first attachment. The body further includes an opening. The opening is located on the center portion and is configured to provide a path for an electrical conduit to be coupled to the second attachment.

A device for mounting sales labels is used to easily mount sales labels onto shelving systems of retail stores. The device comprises a label housing unit, one or more spring-loaded attachment legs and a lever. The device has a first disengaged position where the device may be easily mounted onto a channel on the shelving system and a second engaged position where the device is locked in place on the channel.

A mobile device mounting system includes a device case and a mount. The device case includes: an insert including a rectangular bore and defining a set of undercut sections about the rectangular bore; and a first set of magnetic elements arranged in a first pattern about the rectangular bore. The mount includes: a body; a polygonal boss extending from the body and configured to insert into the rectangular bore; a set of locking jaws arranged on the polygonal boss configured to transiently mate with the set of undercut sections to constrain the polygonal boss within the rectangular bore; and a second set of magnetic elements arranged in a second pattern about the polygonal boss and configured to transiently couple to the first set of magnetic elements to transiently retain the mount against the device case and to drive the set of locking jaws toward the set of undercut sections.

Generally, this disclosure enables various mounting interfaces, devices therewith, accessories therefor, and methods of manufacture and use thereof. In particular, these mounting interfaces include a latch configured to engage with a detent of an accessory (e.g., a smartphone, a dedicated navigation device, a storage container, a drinking bottle) in order to (a) allow the accessory to be easily mounted thereon and unmounted therefrom and (b) hold the accessory sufficiently securely when the accessory is mounted thereon.

Disclosed herein is a camera unit including a camera main body, and a stand configured to support the camera main body, in which the camera main body includes a light receiving section and a main body housing in which the light receiving section is accommodated, the stand includes a first arm portion configured to support the main body housing for pivotal motion such that an orientation in an upward and downward direction of an optical axis of the light receiving section is adjustable, and a second arm portion attached for pivotal motion to the first arm portion, and the main body hosing has a protrusion that projects downwardly at a lower portion of the camera unit in a use state of the camera unit.

A gimbal includes a control device configured to receive an action instruction including a press action instruction and, based on the action instruction, generate a control instruction including a switch control instruction for switching operating modes of the gimbal, a controlling assembly configured to receive the control instruction and generate a performing instruction based on the control instruction for controlling an optical device, and a performing assembly configured to receive and implement the performing instruction. The performing assembly is operably connected to the controlling assembly and supported on a top end of a support arm of the control device. The performing assembly comprises a first rotation member, a second rotation member, and a carrying member connected one to another, and first and second motors for driving the second rotation member and the carrying member to rotate relative to the first and second rotation members, respectively.

A mount system for machine-vision equipment that is located and used outdoors is disclosed. The mount system has a rectangular base, a lower swivel, a puck, and an upper swivel, among other parts. The lower swivel has an aperture with a conical (tapered) surface sunk into its body. This inward-facing conical aperture corresponds in size, shape, and taper with a conical (tapered) protrusion located within the upper swivel. When the mount system is fully assembled, the lower swivel is fastened to the rectangular base using the puck. When fully assembled, a tapered-head screw fastens the upper swivel to the lower swivel by matching the tapered aperture with the conical protrusion.

A product dispenser holder comprises a dispenser holder body configured to receive a product dispenser that stores a supply of a product to be dispensed, an actuation sensor that senses actuations of the product dispenser, and an actuation button, such that when an actuation force is applied to a pump of the product dispenser, a substantially downward force is applied to the actuation button causing the actuation button to rotate substantially downwardly and actuate the actuation sensor to generate a dispenser actuation signal.

A track mounted workstation assembly is disclosed having a housing including a track and one or more communication or electrical or communication ports, and one or more roller mount assemblies further including a sliding carriage configured to slide along the track. In addition, the mounts may further include wiring and cables configured to communicate with the communication or electrical ports of the track housing at either ends. In addition, the mounts may further include one or more receiving members for receiving one or more articulating arms for monitors, peripherals, and other equipment.