A levitating bicycle hub coupling structure using a magnet in the internal contact structure is provided. The levitating bicycle hub coupling structure in which a non-contact type structure in a levitated form is provided to reduce friction enables the position of a hub inner shaft member for transmitting the load of a user to an inner bearing part to be changed to an upper or lower preset position, and fixes the shaft member at a changed position so as to offset the load applied to the shaft member by the repulsive force of the magnets, such that the load is not applied to the bearing parts positioned at both sides of the shaft member or is significantly reduced so as to improve rolling performance, and thus riding of the bicycle becomes smoother and easier.

A variable length connecting rod includes: a connecting rod body; an eccentric member which can swivel with respect to the connecting rod body and in which the effective length of the variable length connecting rod is changed when swiveled; a first piston mechanism making the eccentric member swivel in one direction when hydraulic fluid is fed; a second piston mechanism making the eccentric member swivel in the opposite direction when hydraulic fluid is fed; and a flow direction changing mechanism switching flow directions of hydraulic fluid between the first and second piston mechanisms. The first piston mechanism and second piston mechanism are formed so that a first cylinder volume defined by a stroke length of the first piston and a cross-sectional area of the first cylinder is equal to a second cylinder volume defined by a stroke length of the second piston and a cross-sectional area of the second cylinder.

A variable length connecting rod includes: a connecting rod body; an eccentric member which can swivel with respect to the connecting rod body and in which the effective length of the variable length connecting rod is changed when swiveled; a first piston mechanism making the eccentric member swivel in one direction when hydraulic fluid is fed; a second piston mechanism making the eccentric member swivel in the opposite direction when hydraulic fluid is fed; and a flow direction changing mechanism switching flow directions of hydraulic fluid between the first and second piston mechanisms. The first piston mechanism and second piston mechanism are formed so that a first cylinder volume defined by a stroke length of the first piston and a cross-sectional area of the first cylinder is equal to a second cylinder volume defined by a stroke length of the second piston and a cross-sectional area of the second cylinder.

A variable length connecting rod includes a connecting rod body, an eccentric member, a switching mechanism and a stopping mechanism. The eccentric member is provided at a small diameter end of the connecting rod body. The eccentric member rotates such that an effective length of the variable length connecting rod is varied. The switching mechanism includes a hydraulic piston connected to the eccentric member. The eccentric member reaches a first position when the switching mechanism is in a first state. The eccentric member reaches a second position when the switching mechanism is in a second state. The stopping mechanism includes a stopping member that abuts against or engages with the eccentric member or the hydraulic piston such that the eccentric member is maintained at an intermediate position between the first position and the second position.

A connecting rod (10) has a crankpin bearing eye (11) attached to a crankshaft (38) and a connecting-rod bearing eye (12) attached to a piston. An eccentric adjustment device (13) adjusts an effective connecting rod length and has eccentric rods (15, 16) that engage a lever (14) of the eccentric adjustment device (13). Each eccentric rod (15, 16) has a piston (20, 21) guided in a hydraulic chamber (22, 23). The hydraulic chambers (22, 23) can be charged with hydraulic oil from first hydraulic lines (41) that lead to the crankpin bearing eye (11) and second hydraulic oil lines (24, 25) that lead from the crankpin bearing eye (11). Check valves (26, 27) prevent a backflow of hydraulic oil back into the second hydraulic lines (24, 25). At least one filter prevents an ingress of contaminants from the crankshaft into the hydraulic chambers (22, 23) via the hydraulic oil.

A connecting rod (10) has a crankpin bearing eye (11) attached to a crankshaft (38) and a connecting-rod bearing eye (12) attached to a piston. An eccentric adjustment device (13) adjusts an effective connecting rod length and has eccentric rods (15, 16) that engage a lever (14) of the eccentric adjustment device (13). Each eccentric rod (15, 16) has a piston (20, 21) guided in a hydraulic chamber (22, 23). The hydraulic chambers (22, 23) can be charged with hydraulic oil from first hydraulic lines (41) that lead to the crankpin bearing eye (11) and second hydraulic oil lines (24, 25) that lead from the crankpin bearing eye (11). Check valves (26, 27) prevent a backflow of hydraulic oil back into the second hydraulic lines (24, 25). At least one filter prevents an ingress of contaminants from the crankshaft into the hydraulic chambers (22, 23) via the hydraulic oil.

Disclosed are apparatuses and methods for forming films having uniform thicknesses across the entire width of the film. The films are also disclosed. The apparatus for forming the film includes a first nip roller and a second nip roller, each of the first nip roller and the second nip roller being configured to compress the powder as it passes between the first nip roller and the second nip roller and thereby form the film, whereby in the absence of a force counteracting the pressure of the passage of the powder between the first nip roller and the second nip roller the first nip roller is deflected to a greater degree than the second nip roller. Furthermore, the first nip roller and the second nip roller are each associated with one or more eccentric bearings that rotate to apply force vectors to the first nip roller and the second nip roller.

An actuating device (11) is provided for changeover valves (10) of an internal combustion engine having an adjustable compression ratio. Each changeover valve (10) is used to control a hydraulic oil flow in hydraulic chambers of an eccentric adjusting device of a respective connecting rod (1) of the internal combustion engine. Each changeover valve (10) has a pick-off element (12) that can be actuated by the actuating device (11). The actuating device (11) has a selector fork (13) for each changeover valve (10) and hence for each pick-off element (12) to be actuated. The selector forks are secured on a support structure (14) and can be moved from a first selection position into a second selection position against the restoring force of a return element (22), and wherein the restoring force of the return element (22) moves the selector forks (13) automatically in the direction of the first selection position.

A rescue vehicle (2) includes a chassis (4), a drive unit (6) fastened to the chassis (4) and a driver's cab (8), which is fastened to the chassis (4). The chassis (4) is arranged behind the driver's cab (8) in a longitudinal direction L of the rescue vehicle (2). The rescue cab (10) has a gas-tight configuration. The rescue cab (10) has at least one door (12) as an access to the interior (14) of the rescue cab (10). The rescue vehicle (2) has an air supply unit (16), which is configured to supply the interior (14) of the rescue cab (10) with breathing air.

A connecting rod for an internal combustion engine having an adjustable length between a first connecting rod eye and a second connecting rod eye. An eccentric member having a bearing bore which is positioned eccentrically to an outer diameter is rotated to adjust the length. The eccentric member is rotated by a rack and pinion drive and a double acting hydraulic cylinder.