The present invention relates to an apparatus for pressing a secondary battery. The apparatus for pressing a secondary battery comprises a disposing member on which the secondary battery comprising an electrode assembly and a pouch is disposed, and a pressing member configured to press the secondary battery disposed on the disposing member, wherein the pressing member comprises an accommodation part pressing jig configured to press an accommodation part of the pouch, in which the electrode assembly is accommodated, in the pouch of the secondary battery disposed on the disposing member, and a sealing part pressing jig configured to press a sealing part formed along an edge surface of the accommodation part in the pouch of the secondary battery disposed on the disposing member, wherein the sealing part pressing jig is coupled to a surface of the accommodation part pressing jig corresponding to the sealing part to press the sealing part through pressing force transmitted from the accommodation part pressing jig.

The present invention provides for a mould set for fabrication of an EPS pallet, a process for making the mould set for fabrication of the EPS pallet, and a process for fabricating the EPS pallet using the mould set. The mould set includes a modular platform mould and a leg mould configured to fabricate a platform section and plurality of leg support sections of the EPS pallet, respectively. The modular platform mould includes a modularity unit which enables alternation of dimension of hollow space which is configured to receive feed of polystyrene beads and thereby enabling moulding of the platform section of varying dimensions from a single mould. The one or more leg support sections are affixed to bottom side of the platform section at predefined locations, based on weight bearing capacity and position of lifting, to form the EPS pallet. The easy customization into various sizes as per requirement using a single mould structure reduces requirement of hoarding various moulds for different dimensions of EPS pallet, thereby significantly reducing the cost of moulding operations.

Systems and methods for rapid mold tooling fabrication using active self-shaping non-Newtonian fluids is provided. The rapid mold fabrication system includes one or more molding units between which molds are formed using compression or injection molding process. Each molding unit includes an array of hydraulic pillars that controllably adjust the position of mold preform layers, and an expandable fluid chamber between the end of the pillars and the preform layer against which a mold is formed. A control system is also provided for controlling the volume of STF within the chamber and for transitioning the STF from a liquid to a solid phase through application of an electrical stimulus. A method is also provided for manufacturing a mold using the system. A method is also provided for measuring the geometric properties of objects using the rapid mold fabrication system.

A mould tool comprising: a first tool part defining a first mould cavity portion; a second tool part defining a second mould cavity portion; and, a cavity alignment system comprising: a temperature control system configured to control the temperature of a first zone of the first tool part to thereby effect thermal expansion and/or contraction in the first zone of the first tool part; a sensor configured to measure movement of a part of the first tool part in response to the said thermal expansion and/or contraction; and, a controller configured to control the temperature control system in response to feedback from the sensor to thereby control the position of the first mould cavity portion relative to the second mould cavity portion.

A tangible structure includes a set of removable and parallel rods, each rod including a head; a set of drive devices, each drive device including a motor element generating a rotational motion to a transverse shaft to transmit a translational motion to a rod, the drive device being piloted in order to transmit a motion to the rod at a given speed and in a given direction; a holding system for the drive devices making the drive devices integral with each other, and a calculator determining a set of pilot set points, each pilot set point being transmitted to a drive device on the basis of a first digital set point.

A system for manufacturing a part includes a mold having a contoured forming surface. The system also includes at least one tension strap, configured to attach to a consolidated laminate sheet, and a heating assembly, positioned relative to the mold and configured to supply heat to the consolidated laminate sheet, when attached to the at least one tension strap, to form a heated consolidated laminate sheet. The system additionally includes a strap retraction mechanism, configured to retract the at least one tension strap, when attached to the consolidated laminate sheet, to force the heated consolidated laminate sheet against the contoured forming surface of the mold. The heating assembly includes a flexible heating element configured to flex to conform to a shape of the heated consolidated laminate sheet as the heated consolidated laminate sheet is forced against the contoured forming surface of the mold.

An example method of forming a composite structure is described that includes applying a laminated charge onto an expandable pallet, moving the expandable pallet at a translation rate and relative to a die conveyor that comprises a plurality of die sections, and driving the plurality of die sections on the die conveyor at an angle relative to the expandable pallet so as to drive the plurality of die sections progressively deeper into a recess defined by the expandable pallet and shape the laminated charge into at least part of a shape of the composite structure.

The invention relates to a crack-split moulding tool for producing a foam particle part, having two mould halves (2, 3). The mould halves (2, 3) are pivotably mounted relative to one another such that they can be arranged at a varying distance from each other in certain sections when being filled with foam particles and when pressing together, are moved together at a varying distance until in a closed position, due to a pivoting movement. As a result, it is possible to homogeneously compress areas of the moulding cavity (6) having a different thickness and to compress in a different manner, area having the same thickness.

A variable mold includes a plurality of hydraulic pin systems. Each pin system includes a valve in fluid communication with a supply of pressurized fluid, a tubing in fluid communication with the valve, and a pin coupled to the tubing. The pin is configured to extend from the tubing in response to the supply of the fluid through the valve to the tubing. A longitudinal axis of each pin is mutually parallel and arranged in a two-dimensional array. The variable mold includes a controller operably coupled to the valves that can control the displacement of each pin. The variable mold may include a pin displacement detector configured to detect a displacement of each pin. The pin displacement detector is operably coupled to the controller. The controller can close each valve in response to the pin displacement detector detecting that the pin corresponding to the valve extends a predetermined distance.

A molding subsystem includes a reconfigurable mold and a control subsystem. The reconfigurable mold includes one or more plates, with each plate including: a plurality of pins defining a molding surface of the reconfigurable mold; a frame which defines a plurality of channels for receiving the plurality of pins; and a plurality of actuators for moving the plurality of pins in a first axial direction. The control subsystem includes a controller operably connected to the plurality of actuators of each plate, such that the controller can communicate instructions to and/or obtain readings therefrom. The molding surface of each plate can be manipulated in response to pin movement to facilitate the manufacture of articles of different shape and dimension. Output data corresponding to a digital model of an article placed in the reconfigurable mold can be generated based on readings obtained by the plurality of actuators of each plate.