A device for manufacturing fibrous board has a board carrier and a plurality of at least four cutting tools for separating a fibrous material, in particular strand-shaped or tape-shaped fibrous material into portions, and for depositing the portions. The board carrier is displaceable below the depositing cutting tools here through in at least one movement direction. The depositing cutting tools are substantially stationary and are disposed beside one another in such a manner that the portions of these depositing cutting tools may be simultaneously deposited beside one another on the board carrier.

Systems and methods utilizing stationary and/or moveable cutting components provide limited interference with web processing operations, such as pad spin and pitch alteration. Heat, laser, fluid, or mechanical cutting operations may be used, including respectively, a heated element (e.g., wire, ribbon, bar, or embossing or perforating element) that may be triggered inductively, water or steam jets, or improved knife/anvil cooperation.

A method of forming a disposable product includes feeding an incoming web of ear material, engaging the web with a rotating anvil, cutting ears from the web via the rotating anvil and interaction thereof with a corresponding die, so as to form pairs of ears having complimentary and nested ear shapes, and coupling the ears to at least one of a wing and a web of chassis material. In feeding the incoming web of ear material, the speed of the web is selectively varied between at least a first speed and a second speed, with the web being fed to the rotating die and anvil at the first speed to result in the cut ear shapes having a first height and the web being fed to the rotating die and anvil at the second speed to result in the cut ear shapes having a second height.

Systems and methods utilizing stationary and/or moveable cutting components provide limited interference with web processing operations, such as pad spin and pitch alteration. Heat, laser, fluid, or mechanical cutting operations may be used, including respectively, a heated element (e.g., wire, ribbon, bar, or embossing or perforating element) that may be triggered inductively, water or steam jets, or improved knife/anvil cooperation.

A station for picking up and delivering shaped sheets that define box-like bodies of different types includes a magazine for the sheets and at least one handling element for at least one sheet at a time.

The magazine accommodates a plurality of mutually aligned and juxtaposed sheets and the at least one handling element includes an end bracket provided with at least one grip element and at least one assembly with arms which are articulated with respect to the bracket and are independently movable with respect to a fixed frame. The bracket can move between a first configuration of alignment with the end sheet accommodated in the magazine, in the condition where the at least one grip element is in contact with the end sheet, and a second configuration of alignment with a conveyance line of the sheets which corresponds to the delivery region.

Systems and methods utilizing stationary and/or moveable cutting components provide limited interference with web processing operations, such as pad spin and pitch alteration. Heat, laser, fluid, or mechanical cutting operations may be used, including respectively, a heated element (e.g., wire, ribbon, bar, or embossing or perforating element) that may be triggered inductively, water or steam jets, or improved knife/anvil cooperation.

Systems and methods utilizing stationary and/or moveable cutting components provide limited interference with web processing operations, such as pad spin and pitch alteration. Heat, laser, fluid, or mechanical cutting operations may be used, including respectively, a heated element (e.g., wire, ribbon, bar, or embossing or perforating element) that may be triggered inductively, water or steam jets, or improved knife/anvil cooperation.

A method of manufacturing a transfer assembly for transferring articles from a first moving carrier to a second moving carrier is provided. The method comprises providing a programmable motor and a motor control system. The motor control system and the programmable motor define an excitation frequency. The method comprises providing a carrier member comprising a housing comprising a wall and shifting a natural frequency of the carrier member by forming the wall with a first carbon fiber layer having a first fiber orientation extending in a first direction and with a second carbon fiber layer having a second fiber orientation extending in a second direction that is different than the first direction. The shifting the natural frequency establishes the natural frequency of the carrier member to be at least 1.1 times greater than or at least 1.1 times less than the excitation frequency.

An apparatus includes a transfer mechanism that transfers discrete articles to a receiving member. The transfer mechanism includes a plurality of transfer pucks that carry discrete articles thereon. Each of the transfer pucks includes a puck body with an article carrying surface having vacuum holes formed therein to retain the discrete article thereon via a vacuum. The article carrying surface includes a central region and at least one side region adjacent the central region, the side region aligned lengthwise along the puck body. Each of the transfer pucks also includes one or more resilient puck inserts positioned about a portion of a perimeter of the transfer puck, with each puck insert engaged with the puck body in a respective side region. The puck inserts are sized to protrude above the article carrying surface and are depressible inward toward the article carrying surface upon an application of force thereto.

The invention relates to a cell stacking system for stacking segments of energy cells, comprisinga feed device which continuously feeds the segments at a feed speed, a discharge device which discharges the segments in stacks, andat least one cell stacking apparatus which receives the segments from the feed device and transfers the segments to the discharge device in a stacked manner, whereinthe cell stacking apparatus has at least one removal apparatus and a depositing element, andthe depositing element has a transfer device, a depositing lever, and a receptacle which can be moved from a receiving position into a dispensing position and vice versa, whereinthe depositing lever removes the segments from the removal apparatus and transfers the segments into the receptacle arranged in the receiving position andthe transfer device can be moved from a ready position into a holding position, whereinthe transfer device is arranged in the holding position during the movement of the receptacle from the receiving position into the dispensing position and forms a intermediate support for depositing the segments.