A glass-melting electrode has a cooling device. The glass-melting electrode has an electrode body with a blind hole, and the cooling device has a cooling tube which can be inserted into the blind hole in order to feed coolant into the blind hole. The cooling device has a flow distributor with at least three outlet openings. The flow distributor is arranged at an end of the cooling tube which has been inserted into the blind hole, such that coolant flows through the flow distributor into the blind hole.

An electric glass hot shop system is described herein that has at least one electrically powered heating unit (e.g., electric furnace, electric glory hole, electric pipe warmer, electric color box, electric annealer, electric crucible kiln) used in the processing of glass.

An assembly for pushing an electrode into a glass melting vessel can include a frame, a shaft, a pusher actuator, a contact mechanism, a master actuator, and a torque limiter. The contact mechanism can be attached to the shaft. The pusher actuator can be mounted to the frame and configured to cause translation of the shaft and the contact mechanism relative to the frame. The master actuator can be operatively connected to the pusher actuator such that operation of the master actuator causes operation of the pusher actuator. The torque limiter can be operatively connected between the master actuator and the pusher actuator, and can be configured to disengage when a rotational force on the master actuator exceeds a predetermined amount.

An assembly for pushing an electrode into a glass melting vessel can include a frame, a shaft, a pusher actuator, a contact mechanism, a master actuator, and a torque limiter. The contact mechanism can be attached to the shaft. The pusher actuator can be mounted to the frame and configured to cause translation of the shaft and the contact mechanism relative to the frame. The master actuator can be operatively connected to the pusher actuator such that operation of the master actuator causes operation of the pusher actuator. The torque limiter can be operatively connected between the master actuator and the pusher actuator, and can be configured to disengage when a rotational force on the master actuator exceeds a predetermined amount.

A directional solidification furnace includes one or more movable cooling plates disposed beneath a crucible. In a first position, the cooling plates are free from contact with a crucible support positioned adjacent the crucible. In a second position, the cooling plates are in contact with the crucible support. A control system is used to control the amount of force exerted by the cooling plates against the crucible.

The present invention relates to a melting device, comprising a melting space in which material can be melted and which is enclosed by at least a bottom wall and a side wall, the melting device further comprising at least one electric heater (E) and at least one submerged burner (F) disposed in the melting space to heat material.

The present invention relates to a melting device, comprising a melting space in which material can be melted and which is enclosed by at least a bottom wall and a side wall, the melting device further comprising at least one electric heater (E) and at least one submerged burner (F) disposed in the melting space to heat material.

Methods and systems include melting or augmenting a melt rate of material in a melter using electromagnetic radiation with a frequency between 0.9 GHz and 10 GHz. In some examples, a power and/or frequency of radiation used may be selected so as to control a temperature of a cold cap in the melter while maintaining emissions from the melter below a threshold level. In this manner, examples described herein may provide for efficient and safe melting and vitrification of radioactive wastes.

Methods and systems include melting or augmenting a melt rate of material in a melter using electromagnetic radiation with a frequency between 0.9 GHz and 10 GHz. In some examples, a power and/or frequency of radiation used may be selected so as to control a temperature of a cold cap in the melter while maintaining emissions from the melter below a threshold level. In this manner, examples described herein may provide for efficient and safe melting and vitrification of radioactive wastes.

An electrode propulsion structure with an unequal propulsion amount based on an electrode erosion rule and an electrode propulsion method are provided. The electrode propulsion structure comprises an electrode, a silver plate disposed within the electrode, and a plurality of propulsion modules disposed at a tail end of the electrode. The electrode includes a plurality of electrode blocks. At least one of the plurality of electrode blocks constitutes an electrode module. The silver plate includes a plurality of silver plate modules. At least one of a plurality of electrode modules is provided with a silver plate module and at least one of the plurality of propulsion modules corresponding to the at least one of plurality of propulsion modules.