Apparatus for winding at least one strip of material for the production of electrical energy storage devices, comprising: a rotatable winding core, configured to grip the strip and actuatable to carry it in rotation and thus form a winding; a feed unit to feed the strip of material; and a handling device configured to move the winding core at least between a winding station, at which the winding core is configured to receive the strip in feeding, grip it and wind it about the rotation axis, and a second station; wherein the handling device is configured to move the winding core from the winding station to the second station during the winding.

A method of manufacturing a winding capacitor package structure is provided. The method of manufacturing the winding capacitor package structure includes: forming a base layer on an inner bottom surface of a casing structure; placing a winding assembly and a part of a conductive assembly inside an accommodating space of the casing structure; sequentially forming a plurality of filling layers between the winding assembly and the casing structure; and then placing a bottom carrier frame on a bottom portion of the casing structure so as to match with the casing structure. The casing structure includes a rough inner surface, and the base layer and the filling layer are limited inside the casing structure through a friction provided by the rough inner surface of the casing structure.

A method of manufacturing a winding capacitor package structure is provided. The method of manufacturing the winding capacitor package structure includes: forming a base layer on an inner bottom surface of a casing structure; placing a winding assembly and a part of a conductive assembly inside an accommodating space of the casing structure; sequentially forming a plurality of filling layers between the winding assembly and the casing structure; and then placing a bottom carrier frame on a bottom portion of the casing structure so as to match with the casing structure. The casing structure includes a rough inner surface, and the base layer and the filling layer are limited inside the casing structure through a friction provided by the rough inner surface of the casing structure.

A winding apparatus for the production of power storage devices comprising: a frame, a first actuator device supported by the frame and comprising a rotor and a first drive element, a support which is driven in rotation by the first actuator device through the first drive element, a second actuator device comprising a second drive element and a non-circular core on which to wind a material; said core being arranged on the support in a rotary manner and being driven in rotation by the second actuator device through the second drive element. The second drive element passes at least partially through the rotor.

A winding apparatus for the production of power storage devices comprising: a frame, a first actuator device supported by the frame and comprising a rotor and a first drive element, a support which is driven in rotation by the first actuator device through the first drive element, a second actuator device comprising a second drive element and a non-circular core on which to wind a material; said core being arranged on the support in a rotary manner and being driven in rotation by the second actuator device through the second drive element. The second drive element passes at least partially through the rotor.

According to a manufacturing method of an electrolytic capacitor according to an embodiment, a fiber film, which serves as a separator, is formed on a surface of a substrate, which serves as an electrode, by ejecting a material liquid against the substrate. When the fiber film is formed, thicker fiber is formed at end parts of the substrate in a width direction, compared to a center part of the substrate in the width direction.

A method of winding coilware via a winding machine having a plurality of winding devices, which are drivable by a plurality of drives which comprise at least a supply roll and a winding body, includes providing the coilware from the supply roll and winding the coilware over at least one deflection roll onto the winding body, where at least one drive is adjusted as a function of a position-dependent compensation signal at least partly compensating a defect, and where the position-dependent compensation signal for the drive is provided by acquiring a time domain interference variable during a winding operation, transforming the acquired interference variable into a frequency domain spectrum, filtering the spectrum via a filter specific to the winding device assigned to the drive, transforming the filtered spectrum back into the time domain to provide a time-dependent compensation signal, and transforming the time-dependent compensation signal into the position-dependent compensation signal.

A method of winding coilware via a winding machine having a plurality of winding devices, which are drivable by a plurality of drives which comprise at least a supply roll and a winding body, includes providing the coilware from the supply roll and winding the coilware over at least one deflection roll onto the winding body, where at least one drive is adjusted as a function of a position-dependent compensation signal at least partly compensating a defect, and where the position-dependent compensation signal for the drive is provided by acquiring a time domain interference variable during a winding operation, transforming the acquired interference variable into a frequency domain spectrum, filtering the spectrum via a filter specific to the winding device assigned to the drive, transforming the filtered spectrum back into the time domain to provide a time-dependent compensation signal, and transforming the time-dependent compensation signal into the position-dependent compensation signal.

A support apparatus for the production of electric energy storage devices comprising a support element, which is linearly movable along a feeding plane, an actuator system, which is configured to drive the support element in an intermittent manner, a first roller, which is configured to be caused to rotate at a variable speed, and a second roller, which is opposite the first roller. A further actuator system is configured to control the speed of the first roller compensating for the intermittent movement of the support element.

A ceramic-wound-capacitor includes a first-electrically-conductive-layer, a dielectric-layer, a second-electrically-conductive-layer, and a protective-coating. The dielectric-layer is formed of lead-lanthanum-zirconium-titanate (PLZT). The protective-coating has a thickness of less than ten micrometers (10 μm) and provides electrical isolation between the first-electrically-conductive-layer and the second-electrically-conductive-layer of the ceramic-wound-capacitor. A method for fabricating the ceramic-wound-capacitor includes the steps of feeding a carrier-strip, depositing a sacrificial layer, depositing a first-electrically-conductive-layer, depositing a dielectric-layer, and depositing a second-electrically-conductive-layer to form an arrangement coupled to the carrier-strip by the sacrificial-layer, separating the arrangement from the carrier-strip and sacrificial-layer, creating an exposed-surface of the first-electrically-conductive-layer, applying a protective-coating to the exposed-surface of the first-electrically-conductive-layer, winding the arrangement with the protective-coating to form a ceramic-wound-capacitor, where the protective-coating is in direct contact with the first-electrically-conductive-layer and the second-electrically-conductive-layer of the ceramic-wound-capacitor.