The disclosure relates to a transfer equipment, an aluminum liquid transfer system and an aluminum liquid transfer method. An exemplary transfer equipment comprises a rail platform; a pushing device; a rotating device; wherein the two ends of the rail platforms are adapted to interface with a rail-type transfer trolley running on the casting line, so that the molten liquid container can be transferred from a rail-type transfer trolley on one casting line to one end of the rail platform, and from the other end of the rail platform to a rail-type transfer trolley on the adjacent other casting line, and the turnplate of the rotating device is adapted to interface with the transfer rail on the rail platform, so that the molten liquid container can be transferred from the transfer rail to the turnplate, and to the transfer rail after the orientation has been changed by rotation on the turnplate.

The present application relates to a bath transfer system with a vessel for receiving molten metal, a duct for conveying the molten metal from the vessel through the duct, a vessel cover for air-tightly sealing a vessel interior, and a tilting mechanism for tilting the vessel. The tilting mechanism includes at least one pedestal that is hingedly connected to the vessel, and a blocking device on the vessel for blocking the pedestal in a functional position, the pedestal being movable from a rest position into the functional position in which the pedestal extends beyond a bottom of the vessel.

The present application relates to a bath transfer system with a vessel for receiving molten metal, a duct for conveying the molten metal from the vessel through the duct, a vessel cover for air-tightly sealing a vessel interior, and a tilting mechanism for tilting the vessel. The tilting mechanism includes at least one pedestal that is hingedly connected to the vessel, and a blocking device on the vessel for blocking the pedestal in a functional position, the pedestal being movable from a rest position into the functional position in which the pedestal extends beyond a bottom of the vessel.

The disclosure relates to a transfer equipment, an aluminum liquid transfer system and an aluminum liquid transfer method. An exemplary transfer equipment comprises a rail platform; a pushing device; a rotating device; wherein the two ends of the rail platforms are adapted to interface with a rail-type transfer trolley running on the casting line, so that the molten liquid container can be transferred from a rail-type transfer trolley on one casting line to one end of the rail platform, and from the other end of the rail platform to a rail-type transfer trolley on the adjacent other casting line, and the turnplate of the rotating device is adapted to interface with the transfer rail on the rail platform, so that the molten liquid container can be transferred from the transfer rail to the turnplate, and to the transfer rail after the orientation has been changed by rotation on the turnplate.

The disclosure relates to a transfer equipment, an aluminum liquid transfer system and an aluminum liquid transfer method. An exemplary transfer equipment comprises a rail platform; a pushing device; a rotating device; wherein the two ends of the rail platforms are adapted to interface with a rail-type transfer trolley running on the casting line, so that the molten liquid container can be transferred from a rail-type transfer trolley on one casting line to one end of the rail platform, and from the other end of the rail platform to a rail-type transfer trolley on the adjacent other casting line, and the turnplate of the rotating device is adapted to interface with the transfer rail on the rail platform, so that the molten liquid container can be transferred from the transfer rail to the turnplate, and to the transfer rail after the orientation has been changed by rotation on the turnplate.

A management system includes: an acquisition unit acquiring melting information pertaining to original molten metal, for each of melting furnaces; a first assignment unit assigning a ladle serial number to a ladle receiving the original molten metal; a melting management unit associating a furnace number, the number of tappings from the one melting furnace, and the melting information on the one melting furnace with each other, and storing associated items; a ladle management unit associating the ladle serial number, the furnace number, and the number of tappings with each other, and storing associated items in a storage medium; and a pouring management unit associating an identifier of the mold with the ladle serial number, in response to the pouring device pouring the molten metal in the conveyed ladle into the mold, and storing associated items in the storage medium.

A management system includes: an acquisition unit acquiring melting information pertaining to original molten metal, for each of melting furnaces; a first assignment unit assigning a ladle serial number to a ladle receiving the original molten metal; a melting management unit associating a furnace number, the number of tappings from the one melting furnace, and the melting information on the one melting furnace with each other, and storing associated items; a ladle management unit associating the ladle serial number, the furnace number, and the number of tappings with each other, and storing associated items in a storage medium; and a pouring management unit associating an identifier of the mold with the ladle serial number, in response to the pouring device pouring the molten metal in the conveyed ladle into the mold, and storing associated items in the storage medium.

To provide a system for producing steel castings that is simple and suitable to continuously produce many small steel castings. A system 1 comprises multiple furnaces 10 that are aligned and hold molten metal for cast steel, a pouring machine 20 that has a ladle 30 that receives the molten metal from the furnaces, wherein the pouring machine travels in parallel to a line of the furnaces and pours the molten metal into a mold 70 by tilting the ladle, a line 60 for conveying the molds that intermittently conveys molds that are aligned in parallel to a direction in which the pouring machine travels, wherein the line is located on the opposite side of the furnaces across the pouring machine, and a temperature sensor 38 that measures a temperature of the molten metal so as to generate an alarm if the temperature is low.

To provide a system for producing steel castings that is simple and suitable to continuously produce many small steel castings. A system 1 comprises multiple furnaces 10 that are aligned and hold molten metal for cast steel, a pouring machine 20 that has a ladle 30 that receives the molten metal from the furnaces, wherein the pouring machine travels in parallel to a line of the furnaces and pours the molten metal into a mold 70 by tilting the ladle, a line 60 for conveying the molds that intermittently conveys molds that are aligned in parallel to a direction in which the pouring machine travels, wherein the line is located on the opposite side of the furnaces across the pouring machine, and a temperature sensor 38 that measures a temperature of the molten metal so as to generate an alarm if the temperature is low.

A system for determining a set temperature of molten metal in a pouring facility includes a temperature sensor configured to detect a molten metal temperature at a nozzle tip of a ladle during pouring processing, and a control unit configured to acquire temperature transition obtained by plotting the molten metal temperature for each mold in each of the pouring processing, wherein the control unit determines the upper limit temperature to cause a percentage of the number of optimum temperature transitions included in a plurality of acquired temperature transitions in the number of the plurality of acquired temperature transitions to become a predetermined percentage, and determines a temperature obtained by adding a drop temperature that is a temperature dropped during conveyance processing and the determined upper limit temperature, as the set temperature.