A cylinder holder for a hydroforming device has a substantially cuboid cylinder holder body with a hydraulic cylinder seat to which a hydraulic cylinder can be fixed. The hydraulic cylinder is configured to supply a hydroforming fluid to a workpiece to be shaped. The cylinder holder further includes a base plate to which the cylinder holder body is fixed at a predetermined angle with an anti-rotation lock unit.

Provided is a method for quick forming of a hot metal sheet. The method relates to a technology for forming a metal sheet part, and solves the problem that the existing hot metal sheet forming technology cannot ensure that a blank is deformed under reasonable temperature and pressure conditions, thereby failing to realize precise and quick forming of a complex metal sheet part, especially a thin-walled part. The method mainly includes the following steps: step one, placing a metal sheet blank to be formed on a forming mold; step two, introducing high-pressure gases with equal pressures simultaneously into upper and lower enclosed cavities respectively formed by the metal sheet blank and the sealing mold, and the metal sheet blank and the forming mold; step three, heating the metal sheet blank to a preset forming temperature condition; step four, quickly releasing the high-pressure gas from the cavity formed by the metal sheet blank and the forming mold, such that the metal sheet blank bulges; and step five, discharging the gas from the cavity formed by the metal sheet blank and the sealing mold, and opening the mold to obtain a formed metal sheet part. The present invention is used for manufacturing a metal sheet part.

An apparatus for forming a panel, including a first face sheet, a second face sheet and a core sheet between the first face sheet and the second face sheet, may include a molding tool defining a forming cavity shaped to correspond to the panel, a heating system positioned adjacent to the forming cavity and configured to heat the forming cavity, and a pressurization system configured to pressurize a cavity volume between the tool and the panel and pressurize a panel volume between the first face sheet and the second face sheet.

An apparatus for forming a panel, including a first face sheet, a second face sheet and a core sheet between the first face sheet and the second face sheet, may include a molding tool defining a forming cavity shaped to correspond to the panel, a heating system positioned adjacent to the forming cavity and configured to heat the forming cavity, and a pressurization system configured to pressurize a cavity volume between the tool and the panel and pressurize a panel volume between the first face sheet and the second face sheet.

A cylinder holder for a hydroforming device has a substantially cuboid cylinder holder body with a hydraulic cylinder seat to which a hydraulic cylinder can be fixed. The hydraulic cylinder is configured to supply a hydroforming fluid to a workpiece to be shaped. The cylinder holder further includes a base plate to which the cylinder holder body is fixed at a predetermined angle with an anti-rotation lock unit.

A method of, and arrangement for, producing shaped hollow metal objects by a hot process. A metal hollow semi-finished-product with at least one opening is heated to a forming temperature and placed into a cavity, whose shape corresponds to the desired final external shape of the hollow object. Then the cavity is sealed and water and/or steam is introduced therein. After the final shape of the semi-finished-product is achieved, the semi-finished-product is removed. The cavity is formed by a split mould, whose opening's entry edge has an expanded portion, against which a sealing feature is oriented. The outer surface of the sealing feature is arranged to close against this expanded portion. The sealing feature is also provided with a means of supply of water and/or steam, and a tube through which the water and/or steam is supplied. This tube extends into the interior space of the semi-finished-product, and can be provided with nozzles.

An aerofoil structure with a hollow cavity is manufactured by diffusion bonding and superplastic forming. Outer panels are formed of a first material; a membrane is formed of a second material. Stop-off material is applied to preselected areas on at least one side of the membrane or of one of the panels so as to prevent diffusion bonding between the panels and the membrane at the preselected areas. The panels and the membrane are arranged in a stack and a diffusion bonding process is performed to bond together the first and second panels and the membrane to form an assembly. A superplastic forming process is performed at a forming temperature to expand the assembly to form the aerofoil structure. The forming temperature is selected so that the second material undergoes superplastic deformation at the forming temperature and the first material does not undergo superplastic deformation at the forming temperature.

An aerofoil structure with a hollow cavity is manufactured by diffusion bonding and superplastic forming. Outer panels are formed of a first material; a membrane is formed of a second material. Stop-off material is applied to preselected areas on at least one side of the membrane or of one of the panels so as to prevent diffusion bonding between the panels and the membrane at the preselected areas. The panels and the membrane are arranged in a stack and a diffusion bonding process is performed to bond together the first and second panels and the membrane to form an assembly. A superplastic forming process is performed at a forming temperature to expand the assembly to form the aerofoil structure. The forming temperature is selected so that the second material undergoes superplastic deformation at the forming temperature and the first material does not undergo superplastic deformation at the forming temperature.

A multi-warm forming device and the forming method are disclosed. A multi-warm forming device according to one or a plurality of exemplary embodiments of the present invention may include: a lower mold die that is disposed on a bolster for a process and in which a mold mounting portion having at least one space portion is formed at a center thereof; a lower mold that is disposed at an upper surface of a mold mounting portion of the lower mold die, in which a plurality of gas supply passages formed therein in a vertical direction are connected to a gas supply device of an outside through a gas supply line, and a lower forming surface is formed at an upper surface thereof; an upper mold that is mounted on a slider of an upper portion to be able to be moved up and down corresponding to the lower mold at an upper portion of the lower mold die, in which an upper forming surface is formed at a lower surface corresponding to the lower mold, an upper mold face surface is formed at a circumference of the upper forming surface, and a plurality of heating cartridges are mounted inside along the upper forming surface and the upper mold face surface; and a blank holder of which the mold mounting portion is inserted into a penetration hole that is formed corresponding to the mold mounting portion, is able to be moved in a vertical direction by a guide post and a cushion spring that are mounted within the lower mold die, and in which a plurality of heating cartridges are mounted along a holder face surface that restrains a material together with the upper mold face surface at an early stage of a forming process.

A multi-warm forming device and the forming method are disclosed. A multi-warm forming device according to one or a plurality of exemplary embodiments of the present invention may include: a lower mold die that is disposed on a bolster for a process and in which a mold mounting portion having at least one space portion is formed at a center thereof; a lower mold that is disposed at an upper surface of a mold mounting portion of the lower mold die, in which a plurality of gas supply passages formed therein in a vertical direction are connected to a gas supply device of an outside through a gas supply line, and a lower forming surface is formed at an upper surface thereof; an upper mold that is mounted on a slider of an upper portion to be able to be moved up and down corresponding to the lower mold at an upper portion of the lower mold die, in which an upper forming surface is formed at a lower surface corresponding to the lower mold, an upper mold face surface is formed at a circumference of the upper forming surface, and a plurality of heating cartridges are mounted inside along the upper forming surface and the upper mold face surface; and a blank holder of which the mold mounting portion is inserted into a penetration hole that is formed corresponding to the mold mounting portion, is able to be moved in a vertical direction by a guide post and a cushion spring that are mounted within the lower mold die, and in which a plurality of heating cartridges are mounted along a holder face surface that restrains a material together with the upper mold face surface at an early stage of a forming process.