Founding
Process, & Facts
founding, the process of pouring molten metal into a cavity that has been molded according to a pattern of the desired shape. When the metal solidifies, the result is a casting—a metal object conforming to that shape. A great variety of metal objects are so molded at some point during their manufacture.
The most common type of mold is made of sand and clay; ceramics, sand with cement, metals, and other materials are also used for molds. These materials are packed over the face of the pattern (usually made of wood, metal, or resin) that forms the cavity into which the molten metal is to be poured. The pattern is removed from the mold when its shape is able to be retained by the mold material. Molds are usually constructed in two halves, and the two halves are joined together once the pattern has been removed from them. Pins and bushings permit precise joining of the two halves, which together are enclosed in a mold box. The metal is then poured into the mold through special gates and is distributed by runners to different areas of the casting. The mold must be strong enough to resist the pressure of the molten metal and sufficiently permeable to permit the escape of air and other gases from the mold cavity; otherwise, they would remain as holes in the casting. The mold material must also resist fusion with the molten metal, and the sand at the mold surface must be closely packed to give a smooth casting surface.
The making of patterns for foundries requires care and skill. Patterns are uniformly larger than the desired casting in order to compensate for shrinkage during drops of temperature and the liquid-to-solid phase change. Polystyrene foam patterns remain in the mold and evaporate upon contact with the poured metal; wax patterns are melted out of the mold prior to the pouring of the molten metal. Metal molds are used in that type of founding known as die-casting. Often a hollow space is desired within the casting; in this case a core of fine sand is placed in one of the mold halves. Core boxes made of wood, metal, or resin are also used in this regard.
Modern foundries capable of large-scale production are characterized by a high degree of mechanization, automation, and robotics, and microprocessors allow for the accurate control of automated systems. Advances in chemical binders have resulted in stronger molds and cores and more accurate castings. Accuracy and purity are increased in vacuum conditions, and further advances are expected from zero-gravity casting in space.
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