A control system for a vacuum arc remelting (VAR) process for a metal includes a direct current (DC) power source, a ram drive, voltage drip short sensor, and a controller, which includes a processor. The drip short sensor may be configured to measure a drip short frequency of the electric arc over a period of time. The controller is configured to determine a real time arc gap length between the electrode tip and the melt pool based on a correlation between the drip short frequency and arc gap length. The controller is further configured to control power input to the electrode by the DC power supply by determining an input power level to input to the electrode based on the real time arc gap length, the input power level configured to generate a desired arc gap length, by the DC power supply, at the input power level.

A control system for a vacuum arc remelting (VAR) process for a metal includes a direct current (DC) power source, a ram drive, voltage drip short sensor, and a controller, which includes a processor. The drip short sensor may be configured to measure a drip short frequency of the electric arc over a period of time. The controller is configured to determine a real time arc gap length between the electrode tip and the melt pool based on a correlation between the drip short frequency and arc gap length. The controller is further configured to control power input to the electrode by the DC power supply by determining an input power level to input to the electrode based on the real time arc gap length, the input power level configured to generate a desired arc gap length, by the DC power supply, at the input power level.

A control system for a vacuum arc remelting (VAR) process for a metal includes a direct current (DC) power source, a ram drive, voltage drip short sensor, and a controller, which includes a processor. The drip short sensor may be configured to measure a drip short frequency of the electric arc over a period of time. The controller is configured to determine a real time arc gap length between the electrode tip and the melt pool based on a correlation between the drip short frequency and arc gap length. The controller is further configured to control power input to the electrode by the DC power supply by determining an input power level to input to the electrode based on the real time arc gap length, the input power level configured to generate a desired arc gap length, by the DC power supply, at the input power level.

A device for positioning at least one electrode for smelting furnaces includes a container made of metal structural work lined with refractory material (crucible) and a water-cooled structure and by a lid or roof with which vertical electrodes are associated, each one being slideably associated with temporary locking elements, such as a column locking clamp. The device is arranged to the side of a smelting furnace and below a parking position of the electrodes in the periods of interruption of operation of the smelting furnace. The device is constituted by a fixed base with which at least one lifting element, which can slide vertically with respect to the fixed base and is provided with elements that are adapted to determine its position in terms of height and is provided with a load cell, is associated in an upper region.

A device for positioning at least one electrode for smelting furnaces includes a container made of metal structural work lined with refractory material (crucible) and a water-cooled structure and by a lid or roof with which vertical electrodes are associated, each one being slideably associated with temporary locking elements, such as a column locking clamp. The device is arranged to the side of a smelting furnace and below a parking position of the electrodes in the periods of interruption of operation of the smelting furnace. The device is constituted by a fixed base with which at least one lifting element, which can slide vertically with respect to the fixed base and is provided with elements that are adapted to determine its position in terms of height and is provided with a load cell, is associated in an upper region.

A system including a graphite electrode having a graphite body with first and second opposed ends. The electrode further includes a threaded connector positioned at one of the first or second ends, and a tag coupled to or positioned in the threaded connector, wherein the tag is configured to transmit a signal including information relating to the electrode.