A fixing body configured to house a movable body including a magnet, and including a coil surrounding an outer periphery of the magnet and an outer yoke surrounding an outer periphery of the coil, the fixing body being configured to support the movable body so as to allow the movable body to vibrate back and forth in a vibration direction orthogonal to a radial direction, wherein the outer yoke includes a plurality of openings dispersed in a circumferential direction and provided at the same position in the vibration direction to keep a balance of a magnetic path configured together with the magnet and the coil in the circumferential direction.

A fixing body configured to house a movable body including a magnet, and including a coil surrounding an outer periphery of the magnet and an outer yoke surrounding an outer periphery of the coil, the fixing body being configured to support the movable body so as to allow the movable body to vibrate back and forth in a vibration direction orthogonal to a radial direction, wherein the outer yoke includes a plurality of openings dispersed in a circumferential direction and provided at the same position in the vibration direction to keep a balance of a magnetic path configured together with the magnet and the coil in the circumferential direction.

A compensating element having a first and a second assembly, wherein a locking mechanism is provided which can be switched over between a first and a second operating state. In the first operating state, the first assembly is connected fixedly to the second assembly and, in the second operating state, the first and second assemblies are connected to each other via a spring mechanism in such a manner that they are movable relative to each other. The locking mechanism includes an electric motor that can be used to switch over between the first and the second operating state. A locking ring is or is not braced against at least three balls depending on its rotational position with respect to a center axis. The locking ring is connected in terms of rotary drive to the electric motor via a torsion spring which is elastic with respect to the center axis.

A shaft of a motor includes a first shaft and a second shaft extending from the first shaft to one axial side. A housing includes a neutralizing device holder that holds a first neutralizing device. The neutralizing device holder includes a seal holder that is arranged radially outward of the second shaft and holds a seal member. The first neutralizing device electrically connects the second shaft and the neutralizing device holder. The seal member seals a gap between the second shaft and the seal holder, and is arranged on the other axial side of the first neutralizing device.

A shaft of a motor includes a first shaft and a second shaft extending from the first shaft to one axial side. A housing includes a neutralizing device holder that holds a first neutralizing device. The neutralizing device holder includes a seal holder that is arranged radially outward of the second shaft and holds a seal member. The first neutralizing device electrically connects the second shaft and the neutralizing device holder. The seal member seals a gap between the second shaft and the seal holder, and is arranged on the other axial side of the first neutralizing device.

A modular motor system and methods wherein at least two dual radial gap motors with attachment points may be joined together in a modular manner for the purpose of providing the capability of incrementally increasing or decreasing the total power output of the modular.

Converting magnet repulsion/attraction force into continuous mechanical energy by simulating the meeting distance of two different magnet using a magnetic shield material. Design uses structure made up of non-magnetic material, inside the structure there is a piston made up of permanent magnet that moves up and down. Another permanent magnet is fitted on top of the structure, facing with same magnetic pole. In between the fixed magnet and moving magnet a layer is made up of magnetic shield material is used to block the magnet fields' passes between the magnets. The shield layer will open when the moving magnet about to move down using the crankshaft and very near to the fixed magnet, so that both magnets will repel each other and push the moving magnet away. When the moving magnet reaches the crankshaft repositioning position then the magnet shield layer on the top will close to block the magnetic fields, by doing this the moving magnet connected to the piston or connecting rod will moves up without facing any repulsive force and the cycle continues to produce continuous energy.

Converting magnet repulsion/attraction force into continuous mechanical energy by simulating the meeting distance of two different magnet using a magnetic shield material. Design uses structure made up of non-magnetic material, inside the structure there is a piston made up of permanent magnet that moves up and down. Another permanent magnet is fitted on top of the structure, facing with same magnetic pole. In between the fixed magnet and moving magnet a layer is made up of magnetic shield material is used to block the magnet fields' passes between the magnets. The shield layer will open when the moving magnet about to move down using the crankshaft and very near to the fixed magnet, so that both magnets will repel each other and push the moving magnet away. When the moving magnet reaches the crankshaft repositioning position then the magnet shield layer on the top will close to block the magnetic fields, by doing this the moving magnet connected to the piston or connecting rod will moves up without facing any repulsive force and the cycle continues to produce continuous energy.

The disclosure relates to a stator module for a linear drive of a container-handling machine in the beverage processing industry, comprising a housing in which a core and at least one coil are arranged, wherein the stator module comprises a media supply for supplying a gas into the interior of the housing and the media supply is adapted to pressurize the interior of the housing, as well as a corresponding container-handling machine and a method of operating a container-handling machine.

The disclosure relates to a stator module for a linear drive of a container-handling machine in the beverage processing industry, comprising a housing in which a core and at least one coil are arranged, wherein the stator module comprises a media supply for supplying a gas into the interior of the housing and the media supply is adapted to pressurize the interior of the housing, as well as a corresponding container-handling machine and a method of operating a container-handling machine.