A camera mount includes a pivotable assembly of a pair of arms and a pocket into which an end of one of the arms is inserted, in one of a plurality of discrete orientations. The arms are pivotably joined to one another by a fastener and permitted to be aligned at one of a plurality of angles. The camera mount is installed in a track, a rail or another system mounted to a fixture of a materials handling facility or another environment, and a camera module is mounted to another end of one of the arms. A position of the camera module is selected by installing the camera mount into a desired location on the track, the rail or the other system. An orientation of the camera module is selected by selecting the one of the plurality of discrete orientations and aligning the arms at one of the plurality of angles.

A camera mount that can provide high stability, ease of operation, and flexible configurations for different applications and installation scenarios. The camera mount has an improved attachment mechanism that provides multiple locking positions and strengthened positioning pins. The camera mount has a plurality of anchoring devices capable of securing the camera mount on different curved surfaces.

A pacifier-securing device includes a spring clamp to hold a pacifier and a gooseneck arm connected to the spring clamp. The spring clamp includes a first arm and a second arm separated by a gap in a longitudinal direction between the first arm and the second arm, such that a mouth shield of the pacifier is held in place by a force exerted by the spring clamp in a transverse direction substantially perpendicular to the longitudinal direction. A handle of the pacifier protrudes from the spring clamp along the transverse direction, and an elongated teat of the pacifier protrudes from the spring clamp in the transverse direction opposite the handle. The gooseneck arm holds the spring clamp in a substantially fixed configuration under a weight of the pacifier.

A cable support comprises an elongate supporting structure configured for attachment to a vertical surface. The cable support comprises a boom arm for supporting a cable wherein the boom arm is arranged to slide along at least a portion of the elongate supporting structure. The cable support further comprises a slidable pivot for supporting the boom arm. When deployed, the boom arm slides down along at least a portion of the elongate supporting structure as the boom arm rotates outwards from the supporting structure to provide lateral support for the cable. The slidable pivot supports the boom arm by sliding downwards along the length of the supporting structure during deployment of the boom arm.

A supporting device including an installation assembly; a first supporting arm assembly having a longitudinal direction, a first end, and a second end; a switching bracket; a bearing unit pivotally connected to the switching bracket; and at least one gas spring is provided. The first end is pivotally connected to the installation assembly. The switching bracket is pivotally connected to the second end of the first supporting arm assembly. The gas spring is disposed in the first supporting arm assembly and is respectively connected to the switching bracket and the installation assembly to provide a supporting force. Each gas spring has a hollow tube, a piston rod, and a compression spring. The piston rod is slidably disposed through the hollow tube and has a head. The head may be varied between maximum and minimum protruding positions relative to the hollow tube. The compression spring is sleeved on the piston rod.

A support stand includes a base and a support bracket. The support bracket has a first side and a second side opposite to each other. The first side is rotatably connected to the base. The support bracket further has a slot extending from the second side toward the first side.

A holding device for human-medicine or veterinary-medicine applications having: a joint between a proximal holding segment and a distal holding segment; wherein one axially displaceable thrust element, in each case is arranged in the holding segments; wherein the joint has a tightening bolt, which defines the pivoting and tightening axis, and has deflection elements, by means of which a thrust force, acting relative to the axis, of the proximal thrust element is deflectable to lock the joint onto the tightening axis and to displace the distal thrust element; and wherein the deflection elements include at least one ramp system with a wedge body. A holding system including the specified holding device and a method for locking the joint of the specified holding device.

A display device is disclosed. The display device includes a display panel, a back cover covering a rear surface of the display panel, a bracket coupled to a rear surface of the back cover, and a support removably coupled to the bracket, wherein the bracket includes a first plate, a second plate facing the first plate, and a link connecting the first plate to the second plate, wherein the second plate includes therein a slot, which is formed toward an inside from a lower side of the second plate and in which the support is movably received, wherein the link includes a lower link, and an upper link disposed above the lower link, and wherein each of the lower link and the upper link extends in a direction intersecting the first plate and the second plate, and is pivotably coupled both to the first plate and to the second plate.

The invention relates to a holding device 020 for human-medicine or veterinary-medicine applications comprising: a joint between a proximal holding segment 001 and a distal holding segment 017; wherein one axially displaceable thrust element 002, 016 in each case is arranged in the holding segments 001, 017; wherein the joint has a tightening bolt, which defines the pivoting and tightening axis, and has deflection elements, by means of which a thrust force, acting relative to the axis, of the proximal thrust element 002 is deflectable to lock the joint onto the tightening axis and to displace the distal thrust element 016; and wherein the deflection elements comprise at least one ramp system with a wedge body 008. The invention further relates to a holding system comprising the specified holding device and a method for locking the joint of the specified holding device 020.

A system includes a base, and an actuator having a first end and a second end. The system also includes a shaft configured to rotate relative to the base, and a drive link fixed to the shaft. The system further includes a support arm. A first end of the support arm being fixed to the shaft such that rotation of the shaft causes commensurate rotation of the support arm. The system also includes a timing link having a first end pivotably connected to the base and a second end opposite the first end. Additionally, the system includes a mount coupled to the second end of the timing link. The mount is configured to maintain a substantially constant orientation relative to the base as the support arm transitions between a raised position and a lowered position.