Rail clip assembly (1), comprising superposable first (10) and second bodies (11) arranged for being removably fastened to a rail support by a connector (9). The first body (10) comprises an abutment surface (121) adapted for abutment with a lateral face of a foot of a rail. The first and second bodies comprise corresponding apertures (122, 112) for receiving the connector (9), one (122) of the apertures being oblong with a longer axis (150) extending in a direction oblique to the abutment surface, to enable the first body to assume different positions relative to the second body. The first and second bodies comprise first corresponding surfaces (123, 111) configured for providing force transmitting contact between the first and second bodies when assembled. The rail clip assembly is characterized in that the first and second bodies comprise second corresponding surfaces (124, 114) configured to enter into force transmitting engagement with each other upon fastening the assembly, which have an inclination at an angle between 20 and 85 relative to the horizontal, such that the engagement of the second surfaces with each other produces a net resulting force on the first body oriented towards the rail and resisting backing movement of the first body away from the lateral face of the rail foot upon fastening the connector.

Rail clip assembly (1), comprising superposable first (10) and second bodies (11) arranged for being removably fastened to a rail support by a connector (9). The first body (10) comprises an abutment surface (121) adapted for abutment with a lateral face of a foot of a rail. The first and second bodies comprise corresponding apertures (122, 112) for receiving the connector (9), one (122) of the apertures being oblong with a longer axis (150) extending in a direction oblique to the abutment surface, to enable the first body to assume different positions relative to the second body. The first and second bodies comprise first corresponding surfaces (123, 111) configured for providing force transmitting contact between the first and second bodies when assembled. The rail clip assembly is characterized in that the first and second bodies comprise second corresponding surfaces (124, 114) configured to enter into force transmitting engagement with each other upon fastening the assembly, which have an inclination at an angle between 20 and 85 relative to the horizontal, such that the engagement of the second surfaces with each other produces a net resulting force on the first body oriented towards the rail and resisting backing movement of the first body away from the lateral face of the rail foot upon fastening the connector.

A rail fixture that may include a plurality of track sections suspending a plurality of rail sections. The rail fixture may further include a traveler that traverses across one of the track sections, and a trolley that traverses across the plurality of rail sections. The rail fixture may further include a motorized winch assembly that may be used to lift a load to be moved toward the rail sections. The rail fixture may be used to move a load from a first location to a second location, for example, through an enclosed space having little clearance.

A hoist support system includes a rail assembly having a rail along which a motor assembly is translatable by actuation of a motor of the motor assembly. The motor assembly is adapted to support a hoist and is communicatively coupled to a control system. The control system is adapted to measure motion of a slung load coupled to the hoist and to determine whether and to what extent the slung load is swinging or otherwise unstable. In response to such measurements, the control system transmits control signals to the motor of the motor assembly to change the position of the motor assembly along the rail and attenuate the motion of the slung load.

A hoist support system includes a rail assembly having a rail along which a motor assembly is translatable by actuation of a motor of the motor assembly. The motor assembly is adapted to support a hoist and is communicatively coupled to a control system. The control system is adapted to measure motion of a slung load coupled to the hoist and to determine whether and to what extent the slung load is swinging or otherwise unstable. In response to such measurements, the control system transmits control signals to the motor of the motor assembly to change the position of the motor assembly along the rail and attenuate the motion of the slung load.

A transport facility includes a guide rail which is disposed along a travel path extending in a travel direction through an opening of a wall and which is configured to guide traveling of a transport vehicle, and a fire door configured to open and close the opening. The fire door is configured to, in closing the opening, move toward a first side in an arrangement direction from an open position to a closed position. The fire door includes a notch penetrating the fire door in the travel direction and open on the first side to prevent the fire door from coming into contact with the first rail body and the second rail body while the fire door is moving from the open position to the closed position.

A transport facility includes a guide rail which is disposed along a travel path extending in a travel direction through an opening of a wall and which is configured to guide traveling of a transport vehicle, and a fire door configured to open and close the opening. The fire door is configured to, in closing the opening, move toward a first side in an arrangement direction from an open position to a closed position. The fire door includes a notch penetrating the fire door in the travel direction and open on the first side to prevent the fire door from coming into contact with the first rail body and the second rail body while the fire door is moving from the open position to the closed position.

An embodiment of the present disclosure provides an overhead hoist transport system including: a driving rail configured to extend in a first direction; a support rail positioned parallel to the driving rail; and a crane movably connected to the driving rail and the support rail and configured to move along the driving rail and the support rail, wherein the crane includes: a base configured to extend in a second direction perpendicular to the first direction to cross the driving rail and the support rail; a driving wheel connected to the base and configured to move along the driving rail; and a guide wheel connected to the base and pressed toward a contact surface of the support rail to remain in contact with the support rail, the contact surface being a surface in contact with the guide wheel.

An embodiment of the present disclosure provides an overhead hoist transport system including: a driving rail configured to extend in a first direction; a support rail positioned parallel to the driving rail; and a crane movably connected to the driving rail and the support rail and configured to move along the driving rail and the support rail, wherein the crane includes: a base configured to extend in a second direction perpendicular to the first direction to cross the driving rail and the support rail; a driving wheel connected to the base and configured to move along the driving rail; and a guide wheel connected to the base and pressed toward a contact surface of the support rail to remain in contact with the support rail, the contact surface being a surface in contact with the guide wheel.

A rail fastening device (100) comprises a lower plate (11) and an upper plate (12) provided with a pair of clips (13) for engaging the rail 16, the upper plate (12) being fastened to the lower plate (11) by a pair of fastening bolts (19) which extend through respective apertures (20) in the upper plate (12), the fastening bolts (19) being slidably mounted to the lower plate (11) for movement in a direction which, in use, extends transverse the rail (16). A jacking bolt (31) is arranged to lift the upper plate away from the lower plate as the bolt (31) is tightened and vice-versa. An alignment bolt extends 33 laterally between the upper and lower plates (11), (12) and is rotatable to displace the upper plate (12) laterally relative to the lower plate (11). A levelling bolt (102) threadably engaged with the lower plate is arranged to lift the lower plate (11) away from the surface on which the device (100) is seated as the bolt (102) is tightened and vice-versa.