The invention relates to a method and a device for casting a melt 4 of a metallic material by means of a furnace 2 of a low pressure casting device, which furnace 2 has a receiving space 3 and a riser tube protruding into said receiving space 3. By pressurizing the receiving space 3 with compressed air, the melt 4 in the riser tube 12 of the furnace 2 is pressed into a mold cavity 10 of a mold 7, wherein simultaneously, a magnetic field acting against the conveying direction 23 of the melt 4 is applied to the melt 4 of the metallic material by means of a magnetic element 16 arranged in the region of the riser tube 12.

A multi-position parallel pressurized casting device for large aluminum alloy castings and method thereof are provided. The device includes a platform, a top surface of the platform is a working surface, and a bottom of the platform is provided with a holding furnace. A number of the holding furnace is two or more, and each holding furnace is connected to a liquid filling port corresponding to the working surface by a separate lift device, and the holding furnaces can achieve independent liquid level pressure control or synchronization liquid level pressure control in any combination by a lift control system; and a cover body is also provided on the working surface, the cover body and the working surface form a sealed working chamber. A vacuum-pumping system and an inert gas replacement system for the working chamber and/or the holding furnace are further provided.

A multi-position parallel pressurized casting device for large aluminum alloy castings and method thereof are provided. The device includes a platform, a top surface of the platform is a working surface, and a bottom of the platform is provided with a holding furnace. A number of the holding furnace is two or more, and each holding furnace is connected to a liquid filling port corresponding to the working surface by a separate lift device, and the holding furnaces can achieve independent liquid level pressure control or synchronization liquid level pressure control in any combination by a lift control system; and a cover body is also provided on the working surface, the cover body and the working surface form a sealed working chamber. A vacuum-pumping system and an inert gas replacement system for the working chamber and/or the holding furnace are further provided.

The present application discloses an aluminum alloy low-pressure casting device and an aluminum alloy low-pressure casting process. A riser tube is canceled, and the pressure kettle replaces original injection of compressed air into a holding furnace, thereby reducing the consumption of compressed air, and improving the production efficiency of the low-pressure casting process. A non-return stopper is used to space the low-pressure casting and the holding furnace, and molten aluminum alloy can be added into the holding furnace in real time without interrupting the low-pressure casting process, so that rejects affected by temperature field changes due to interrupt of the continuous casting process can be reduced, and the yield of the casting process is improved.

The present application discloses an aluminum alloy low-pressure casting device and an aluminum alloy low-pressure casting process. A riser tube is canceled, and the pressure kettle replaces original injection of compressed air into a holding furnace, thereby reducing the consumption of compressed air, and improving the production efficiency of the low-pressure casting process. A non-return stopper is used to space the low-pressure casting and the holding furnace, and molten aluminum alloy can be added into the holding furnace in real time without interrupting the low-pressure casting process, so that rejects affected by temperature field changes due to interrupt of the continuous casting process can be reduced, and the yield of the casting process is improved.

A casting system is provided with at least two low-pressure casting furnaces. Each of the at least two low-pressure casting furnaces is adapted to be connected in fluid communication with a mold. At least one controller is in cooperation with the at least two low-pressure casting furnaces to collectively operate the low-pressure casting furnaces to cast a material into the mold.

A casting system is provided with at least two low-pressure casting furnaces. Each of the at least two low-pressure casting furnaces is adapted to be connected in fluid communication with a mold. At least one controller is in cooperation with the at least two low-pressure casting furnaces to collectively operate the low-pressure casting furnaces to cast a material into the mold.

A low-pressure casting unit capable of alternately using crucible type heat preservation furnaces, consisting of a low-pressure casting machine, a crucible type heat preservation furnace I, a crucible type heat preservation furnace II, a trolley transfer system, a heat preservation furnace lifting system, a control system, and a transversely moving guide rail, the heat preservation furnace lifting system being arranged at a bottom of the low-pressure casting machine, the heat preservation furnace lifting system lifting the crucible type heat preservation furnace I or the crucible type heat preservation furnace II up and down in the low-pressure casting machine, one side of the low-pressure casting machine being provided with a trolley transfer system in front and the trolley transfer system moving on the transversely moving guide rail. According to the invention, the concept is ingenious, the alternative use of the two crucible type heat preservation furnaces can be realized only by adding a transversely moving guide rail on the outer side of the low-pressure casting machine and adding a transfer trolley. The problem of aluminum slags deposited at the bottom of the crucible type heat preservation furnace is well solved.

A low-pressure casting unit capable of alternately using crucible type heat preservation furnaces, consisting of a low-pressure casting machine, a crucible type heat preservation furnace I, a crucible type heat preservation furnace II, a trolley transfer system, a heat preservation furnace lifting system, a control system, and a transversely moving guide rail, the heat preservation furnace lifting system being arranged at a bottom of the low-pressure casting machine, the heat preservation furnace lifting system lifting the crucible type heat preservation furnace I or the crucible type heat preservation furnace II up and down in the low-pressure casting machine, one side of the low-pressure casting machine being provided with a trolley transfer system in front and the trolley transfer system moving on the transversely moving guide rail. According to the invention, the concept is ingenious, the alternative use of the two crucible type heat preservation furnaces can be realized only by adding a transversely moving guide rail on the outer side of the low-pressure casting machine and adding a transfer trolley. The problem of aluminum slags deposited at the bottom of the crucible type heat preservation furnace is well solved.

A vacuum smelting device with mold-temperature control design includes: a chamber body and a cabin door, wherein the chamber body and the cabin door form a vacuum closed space; a smelting crucible disposed in the vacuum closed space for smelting raw materials to a molten metal; a casting mold also disposed in the vacuum closed space for accommodating the molten metal poured from the smelting crucible, and solidifying the molten metal to an as-cast alloy; and a mold-temperature control module surrounding the casting mold for controlling the temperature of the casting mold.