A slat conveyor has a plurality of slat bodies supported between a pair of left and right driving endless turning bodies by concentric horizontal support shafts and has a pair of front and rear guide rollers supported to a guide rail laid on each of upper and lower horizontal path sections. A U-turn guiding mechanism at both ends includes the guide rollers, a slat body posture controlling rotating body, and a drive mechanism for the rotating body. The rotating body has the same turning radius as that of the horizontal support shaft on a U-turn path section, and includes an engaging portion for positioning and turning the guide rollers. The drive mechanism drives the rotating body such that the engaging portion is turned in the same direction and at the same speed as the turning speed of the horizontal support shaft on the U-turn path section.

A slat conveyor has a plurality of slat bodies supported between a pair of left and right driving endless turning bodies by concentric horizontal support shafts and has a pair of front and rear guide rollers supported to a guide rail laid on each of upper and lower horizontal path sections. A U-turn guiding mechanism at both ends includes the guide rollers, a slat body posture controlling rotating body, and a drive mechanism for the rotating body. The rotating body has the same turning radius as that of the horizontal support shaft on a U-turn path section, and includes an engaging portion for positioning and turning the guide rollers. The drive mechanism drives the rotating body such that the engaging portion is turned in the same direction and at the same speed as the turning speed of the horizontal support shaft on the U-turn path section.

A loading apparatus for loading food products onto and/or into a slicing apparatus, in particular a high-speed slicer, comprises at least one magazine unit that includes a conveying means that endlessly circulates along a running direction. The conveying means is configured to lift the products to a transferring height at which the products can be transferred to the slicing apparatus and includes several product support surfaces, the product support surfaces being oriented essentially perpendicular to the running direction and positioned subsequently along the running direction with a space between each other. At least one product is loadable onto a respective product support surface for lifting the product to the transferring height.

A loading apparatus for loading food products onto and/or into a slicing apparatus, in particular a high-speed slicer, comprises at least one magazine unit that includes a conveying means that endlessly circulates along a running direction. The conveying means is configured to lift the products to a transferring height at which the products can be transferred to the slicing apparatus and includes several product support surfaces, the product support surfaces being oriented essentially perpendicular to the running direction and positioned subsequently along the running direction with a space between each other. At least one product is loadable onto a respective product support surface for lifting the product to the transferring height.

A funicular intended particularly for transporting heavy loads between an upstream station (10) and a downstream station (12), comprises a railway track (14) connecting the upstream station (10) to the downstream station (12) and a vehicle (16) running on the track (14) and drawn by at least one towing cable (30). The vehicle comprises a chassis (50) defining a median longitudinal vertical plane that rests on at least one pendulum running gear, comprising two independent lateral pendulum devices (60) each comprising a secondary pendulum (62) articulated in relation to the chassis (50) and two primary pendulums, each articulated in relation to the secondary pendulum (62). Each lateral pendulum device (60) comprises a plate (64) connected to the chassis (50) via one or several jacks (66) to which the secondary pendulum device (62) is articulated.

A loading apparatus for loading food products onto and/or into a slicing apparatus, in particular a high-speed slicer, comprises at least one magazine unit that includes a conveying means that endlessly circulates along a running direction. The conveying means is configured to lift the products to a transferring height at which the products can be transferred to the slicing apparatus and includes several product support surfaces, the product support surfaces being oriented essentially perpendicular to the running direction and positioned subsequently along the running direction with a space between each other. At least one product is loadable onto a respective product support surface for lifting the product to the transferring height.

A loading apparatus for loading food products onto and/or into a slicing apparatus, in particular a high-speed slicer, comprises at least one magazine unit that includes a conveying means that endlessly circulates along a running direction. The conveying means is configured to lift the products to a transferring height at which the products can be transferred to the slicing apparatus and includes several product support surfaces, the product support surfaces being oriented essentially perpendicular to the running direction and positioned subsequently along the running direction with a space between each other. At least one product is loadable onto a respective product support surface for lifting the product to the transferring height.

A link conveyor for an assembly machine and methods for chordal compensation in a link conveyor, may include a first upper chordal compensation cam in the upper rail assembly at the first end of the frame to deflect the chain by a first upper variable deflection amount; a first lower chordal compensation cam in the lower rail assembly at the first end of the frame to deflect the chain by a first lower variable deflection amount; and configuring the first upper variable deflection amount and the first lower variable deflection amount to reduce deviation between a first velocity of the chain at the first end of the frame and a second velocity of the chain at the second end of the frame.

A link conveyor for an assembly machine and methods for chordal compensation in a link conveyor, may include a first upper chordal compensation cam in the upper rail assembly at the first end of the frame to deflect the chain by a first upper variable deflection amount; a first lower chordal compensation cam in the lower rail assembly at the first end of the frame to deflect the chain by a first lower variable deflection amount; and configuring the first upper variable deflection amount and the first lower variable deflection amount to reduce deviation between a first velocity of the chain at the first end of the frame and a second velocity of the chain at the second end of the frame.

A slicing apparatus for slicing food products into slices comprises a feeding unit configured to feed products along a feeding direction into a cutting region in which a blade for slicing the products into slices is arranged, wherein the feeding unit comprises a moving device that is configured to move the products into the cutting region, and wherein the moving device comprises a transporting member that is configured to apply a pressure onto an upper product side while the product is fed into the cutting region.