Disclosed is an arresting system for arresting a swivel motion between two swivel-mounted elements, including a brake rod connected to the first element, an arresting device on the second element with a housing, through which the brake rod extends, in which case the arresting device has a drive and at least one brake-shoe element that can be moved via the drive relative to the brake rod. The brake-shoe element is inside the housing and engageable with the brake rod upon exertion of a braking force. Included are a sensor, and an electronic device controlling braking force exerted by the brake-shoe element on the brake rod depending on the signals from the sensor. The drive is an electric motor driving in rotation an actuation element that, to produce the relative motion between the brake-shoe element and the brake rod, has an actuation cam acting on the brake-shoe element.

Disclosed is an arresting system for arresting a swivel motion between two swivel-mounted elements, including a brake rod connected to the first element, an arresting device on the second element with a housing, through which the brake rod extends, in which case the arresting device has a drive and at least one brake-shoe element that can be moved via the drive relative to the brake rod. The brake-shoe element is inside the housing and engageable with the brake rod upon exertion of a braking force. Included are a sensor, and an electronic device controlling braking force exerted by the brake-shoe element on the brake rod depending on the signals from the sensor. The drive is an electric motor driving in rotation an actuation element that, to produce the relative motion between the brake-shoe element and the brake rod, has an actuation cam acting on the brake-shoe element.

The present disclosure discloses an assemblable storage box. A box body comprises a bottom plate and four side plates, the four side plates comprise a front side plate, a rear side plate, a left side plate, and a right side plate, two adjacent side plates of the four side plates are detachably clamped together, bottom portions of the four side plates are disposed with support countertops, four sides of the bottom plate horizontally extend outward to define positioning edges, the positioning edges of the four sides of the bottom plate respectively abut the support countertops of the four side plates, and the positioning fasteners are fastened to the support countertops to enable the positioning edges to be positioned relative to the support countertops.

A door holding device and system is disclosed that holds a door in a partially open configuration. The door holding device includes a first arm assembly that attaches to a door, a second arm assembly that attaches to a door frame, a movable clamping mechanism that clamps the second arm assembly to the door frame, and a pivot device that allows the first arm assembly and the second arm assembly to pivot with respect to each other.

A door holding device and system is disclosed that holds a door in a partially open configuration. The door holding device includes a first arm assembly that attaches to a door, a second arm assembly that attaches to a door frame, a movable clamping mechanism that clamps the second arm assembly to the door frame, and a pivot device that allows the first arm assembly and the second arm assembly to pivot with respect to each other.

A surface-mounted device for controlling the swing/rotational motion of a hinged door/panel system. Said device controls the velocity of the door/panel's and provides check point(s) in the pathway of its motion. The device includes a non-pivoting carrier component to be fixed upon a hinged door/panel, a non-pivoting receiver component fastened to the adjacent and separate area which shares a common hinge(s)/axis with the movable door/panel and a flexible control arm component firmly attached at one end to the carrier. The flexible control arm is aligned with the receiver's through-body aperture by means of the carrier's fixed position on a movable hinged door/panel and provides control of the door/panel by means of passing into and through the aperture provisioned in the receiver in a linear manner to provide both speed and positional check control (motion detents) of the door's potential swing arc path. The speed control aspect of the device is accomplished by means of controlled frictional contact between the flexible control arm's component material(s) and the receiver's aperture and this effect is enhanced by means of the temporary physical deformation exhibited by the flexible control arm whilst it is undergoing loading stresses as it passes within the constriction of the receiver's aperture geometry, its component materials and the energized spherical element acting upon the wide surface of the flexible control arm by limiting frictional contact between the flexible control arm and the receiver's aperture when the energized spherical element is not engaged with the flexible control arm's provisioned negative areas(s) and the attached door/panel is in motion. Maximum frictional force is delivered by the device when the spherical element engages a provisioned negative area on the flexible control arm, thus creating a check in the door/panel swing path. The device may be added/retrofitted to the surfaces of a pre-existing or new hinged door/panel system without significant design or structural modifications of said hinged door/panel systems and their associated components.

A surface-mounted device for controlling the swing/rotational motion of a hinged door/panel system. Said device controls the velocity of the door/panel's and provides check point(s) in the pathway of its motion. The device includes a non-pivoting carrier component to be fixed upon a hinged door/panel, a non-pivoting receiver component fastened to the adjacent and separate area which shares a common hinge(s)/axis with the movable door/panel and a flexible control arm component firmly attached at one end to the carrier. The flexible control arm is aligned with the receiver's through-body aperture by means of the carrier's fixed position on a movable hinged door/panel and provides control of the door/panel by means of passing into and through the aperture provisioned in the receiver in a linear manner to provide both speed and positional check control (motion detents) of the door's potential swing arc path. The speed control aspect of the device is accomplished by means of controlled frictional contact between the flexible control arm's component material(s) and the receiver's aperture and this effect is enhanced by means of the temporary physical deformation exhibited by the flexible control arm whilst it is undergoing loading stresses as it passes within the constriction of the receiver's aperture geometry, its component materials and the energized spherical element acting upon the wide surface of the flexible control arm by limiting frictional contact between the flexible control arm and the receiver's aperture when the energized spherical element is not engaged with the flexible control arm's provisioned negative areas(s) and the attached door/panel is in motion. Maximum frictional force is delivered by the device when the spherical element engages a provisioned negative area on the flexible control arm, thus creating a check in the door/panel swing path. The device may be added/retrofitted to the surfaces of a pre-existing or new hinged door/panel system without significant design or structural modifications of said hinged door/panel systems and their associated components.

A stopper for stopping rotation of a planar element with respect to a frame when the planar element is hinged to the frame, the stopper has a longitudinal axis and comprises: a locking bar having a toothed surface and received within an indentation, an operation handle for moving the locking bar out of the indentation, a locking spring having a locking tooth that is urged into the toothed surface, a releasing lever for releasing the locking tooth from the toothed surface, a retention spring for urging the locking bar into the indentation. A linear movement of the operation handle moves a portion of the locking bar out of the indentation, the locking bar abuts against the frame, and, the locking bar is fixed in its position by means of the locking tooth that is urged against the toothed surface.

A stopper for stopping rotation of a planar element with respect to a frame when the planar element is hinged to the frame, the stopper has a longitudinal axis and comprises: a locking bar having a toothed surface and received within an indentation, an operation handle for moving the locking bar out of the indentation, a locking spring having a locking tooth that is urged into the toothed surface, a releasing lever for releasing the locking tooth from the toothed surface, a retention spring for urging the locking bar into the indentation. A linear movement of the operation handle moves a portion of the locking bar out of the indentation, the locking bar abuts against the frame, and, the locking bar is fixed in its position by means of the locking tooth that is urged against the toothed surface.

The pop-up apparatus for a vehicle door, includes a door check to be fixed to a vehicle door, a check link having one end supported to be supported on a body so as to be turnable, the check link being configured to perform relative movement with respect to the door check between the one end and another end of the check link while being applied with a pushing force by the door check, a push arm, which is arranged on a side closer to the another end of the check link, and is configured to turn about a rotation axis to apply a force so as to cause the relative movement of the check link in a direction in which the vehicle door is opened, a posture arm configured to turn about the rotation axis, and urging means configured to apply an urging force, which enables integral turning of the push arm and the posture arm, to the push arm and the posture arm when the posture arm turns.