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.

A ceramic die for a hot press is provided, along with a method of constructing a ceramic die. The ceramic die includes a ceramic die body defining a mold surface configured to shape a part during a superplastic forming process. The mold surface defines at least one curved surface and at least one non-curved surface, spaced apart from the at least one curved surface. The ceramic die also includes a plurality of fibers disposed within the ceramic die body. The plurality of fibers may be preferentially located proximate the at least one curved surface such that a first portion of the ceramic die body proximate the at least one curved surface has a greater percentage of fibers than a second portion of the ceramic die body proximate the at least one non-curved surface.

A method of forming a part includes: inserting a blank into a die, the die comprising a mold mounted above a sealing counterpart; clamping the blank between the mold and the sealing counterpart; applying first pressure on the blank from the sealing counterpart so the blank is pressed upward to form a shaped part corresponding to the mold; applying a vacuum to the shaped part to hold it against the mold also after separating the mold and the sealing counterpart, the vacuum applied through at least one opening in the mold located in a corner of the mold that the blank does not reach when the first pressure is applied; and discontinuing the vacuum to allow the shaped part to be released from the mold.

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 mold for hot forming of materials in the form of a sheet is disclosed having a first half-shell bearing a die and a second half-shell, between which a chamber for forming the plate is provided. The second half-shell is provided with channels and respective holes for feeding a pressurized gas into the chamber. Inside the die there is at least one ventilated chamber, equipped with heating assemblies and ventilation assemblies for the circulation of hot air inside a ventilated chamber.

Disclosed herein are methods for hydroforming a handpan shell. Hydroforming a handpan shell using a mold complementary to the intended shape of the handpan shell can improve the quality and performance of the handpan while reducing the time and cost needed to form features into the handpan that allow musical tones to be produced.

Disclosed herein are methods for hydroforming a handpan shell. Hydroforming a handpan shell using a mold complementary to the intended shape of the handpan shell can improve the quality and performance of the handpan while reducing the time and cost needed to form features into the handpan that allow musical tones to be produced.

A method is provided for determining a pressure distribution of a molding tool device (1) for reshaping a sheet metal component (2). The pressure distribution represents a load on the sheet metal component (2) caused by reshaping in the molding tool device (1). The method includes introducing a piezoelectric material (3) into a raw material (12) of the sheet metal component (2) to form a composite sheet metal component (4) that provides an electrical voltage under mechanical loads. The method proceeds by arranging the composite sheet metal component (4) in the molding tool device (1) and reshaping the composite sheet metal component (4) with the molding tool device (1). The method then uses at least one sensor device (5) for detecting spatially resolved electric voltage signals that emanate from the composite sheet metal component (4) during the reshaping and determining the pressure distribution using the detected spatially resolved voltage signals.