A linear actuator comprising a housing with a proximal end and a distal end, and defining a central cavity extending axially; a piston tube at least partially positioned axially within the central cavity; a first elongated rotatable screw positioned axially within the central cavity; a first cylindrical nut mounted about the first elongated rotatable screw and configured to move axially as the first elongated rotatable screw rotates; a second elongated rotatable screw positioned axially within the central cavity; a second cylindrical nut mounted about the second elongated rotatable screw and configured to move axially within the central cavity as the second elongated rotatable screw rotates; and a spring positioned around the second elongated rotatable screw between the second cylindrical nut and the distal end of the housing, wherein the spring is configured to bias the second cylindrical nut away from the distal end of the housing.

A gearbox for a vehicle seat adjustment mechanism in accordance with the principles of the present disclosure includes first and second portions. The first portion includes a first body defining a first longitudinal recess and a first peripheral recess in fluid communication with the first longitudinal recess. The first body includes a concave first curved surface. The second portion includes a second body defining a second longitudinal recess and a second peripheral recess in fluid communication with the second longitudinal recess. The second body includes a convex second curved surface. The second curved surface has an equal and opposite curvature compared to the first curved surface. In an assembled configuration, the first and second curved surfaces are in contact, the first longitudinal and second longitudinal recesses cooperate to define a longitudinal passage, and the first and second peripheral recesses communicate to define a peripheral receptacle.

A longitudinal adjuster for a vehicle seat may have a rail assembly having two rail pairs of seat rails. The respective rail pair has a fixed seat rail and a seat rail that is movable relative to the fixed seat rail. The rail assembly may also have a motor unit and a gearbox unit, which couples the motor unit and the movable seat rail. The rail assembly may also comprise a holder for receiving a gearbox housing of the gearbox unit. The holder is arranged with the gearbox unit in a hollow space formed by the one rail pair and is fixed to the movable seat rail. The holder is formed so as to be open at one end and closed at the opposite end. The holder has at least one stiffening element at the open end.

A gearing arrangement (3), for a spindle drive (1), includes a gearing holder (11). At least one pivot axle (y), about which the spindle drive (1) is rotatably and/or pivotably mountable or mounted, and/or at least one receptacle for the at least one pivot axle (y), is formed at least by the gearing housing (4). The gearing holder (11), or the gearing arrangement (3) includes a component group which, as components, includes a gearing housing (4), a gearing holder (11) and a gearing cover (10). At least one pivot axle (y), about which the spindle drive (1) is rotatably and/or pivotably mountable or mounted, is formed by at least one of the components of the component group. At least one receptacle, for the at least one pivot axle (y), is formed by at least one other of the components of the component group.

A method for automatic calibration of a device for actuating at least one element to be actuated in a structure, the actuation device comprising at least one actuator configured to actuate at least one corresponding element to be actuated. The method comprises the steps of: controlling the movement of each actuator to place each element in a predetermined reference position; and for each actuator: controlling the movement of the actuator in a first direction; if the value of a parameter associated with the actuator exceeds a first reference value, controlling the movement of the actuator in a second direction, opposite to the first direction; if the value of the parameter exceeds a second reference value, recording the position occupied by the actuator as the position of a first mechanical stop of the actuator.

A linear actuator comprising a housing with first and second ends, and defining a central cavity extending axially therethrough; a tube having first and second portions, the first portion arranged to slide within the central cavity of the housing, and the second portion extending outwardly from the second end of the housing; a first elongated rotatable screw positioned axially within the central cavity and coaxial with the rube; a first nut mounted about the first elongated rotatable screw and configured to move axially as the first elongated rotatable screw rotates; a second elongated rotatable screw positioned axially within the central cavity; a second nut mounted about the second elongated rotatable screw and configured to move axially within the central cavity as the second elongated rotatable screw rotates; and a spring positioned around the second elongated rotatable screw between the second nut and the second end of the housing.

An extendible protective element for use in a child safety seat is disclosed. The extendible protective element comprises a first thread component comprising a first external thread and a first internal thread, and a second thread component comprising a second external thread, wherein the first thread component is rotatably connected to the second thread component via the first internal thread of the first thread component and the second external thread of the second thread component.

A vehicle seat attachment includes a riser bracket of a vehicle frame. A pin is biased through the riser bracket to a securing position. A seat bracket has an angled channel that extends to a securing aperture, wherein slidable engagement of the angled channel with the pin is configured to bias the pin away from the securing position until the pin reaches the securing aperture wherein the pin returns to the securing position.

A support base for a child safety seat includes a support leg, a first and a second locking mechanism, and a linking assembly. The support leg includes three segments that are telescopically connected with one another via a first and a second sliding connection. The first locking mechanism includes a first latch for locking and unlocking the first sliding connection, and a first actuating part operable to cause the first latch to unlock the first sliding connection. The second locking mechanism includes a second latch for locking and unlocking the second sliding connection, and a second actuating part operable to cause the second latch to unlock the second sliding connection. The linking assembly operatively couples the first locking mechanism to the second locking mechanism so that the first and second sliding connections can be unlocked concurrently with one single operating step.

A linear actuator for adjusting a seat component of a motor vehicle seat includes a lead screw having a rod head. A fastening means is connected to the rod head and connectable to a first seat component of the motor vehicle seat. The first seat component has a bearing, with the fastening means being insertable into the bearing in a first orientation and lockable in the bearing in a second orientation.