In embodiments, a method for operating a glass manufacturing apparatus may include heating a delivery conduit with resistive windings positioned around an exterior surface of the delivery conduit, the delivery conduit extending between a mixing vessel and a delivery vessel. The method may also include injecting electric current through the delivery conduit while heating the delivery conduit with resistive windings and prior to flowing molten glass through the delivery conduit thereby increasing a temperature of the of the delivery conduit, wherein an input heat flux into the delivery conduit is greater than an output heat flux away from the delivery conduit prior to flowing molten glass through the delivery conduit.

Method and apparatus for removing bubbles from a molten substrate. The molten substrate from a furnace passes through a downtube to reach additional manufacturing tools, such as an extrusion bushing. One or more ultrasonic sensors are arranged along the downtube. The ultrasonic sensor(s) transmit ultrasonic energy into the molten substrate and measure a characteristic of the ultrasonic energy, such as a propagation time for the ultrasonic energy to be reflected back to the ultrasonic sensor(s). A bubble is detected when a change in the characteristic of the ultrasonic energy is detected. When a bubble is detected, flow through the downtube is diverted to a duct to remove a slug of molten substrate that includes the bubble.

A molten glass cutting apparatus comprises a pair of shear blades and a control unit that controls a pair of the shear blades to relatively move toward each other. The control unit controls a pair of the shear blades to relatively move so that tip parts of a pair of the shear blades overlap, and shearing force by cutting edges of a pair of the shear blade cuts molten glass extruded from an orifice formed at a bottom part of a spout. When a central part of molten glass is offset with respect to a central axis of the orifice, the control unit offsets a position of cutting by a pair of the cutting edges to a side of the central part with respect to the central axis.

A cutting assembly is provided with a supporting frame, with two shear cutting members revolving with respect to the supporting frame about respective hinge axes, parallel to each other, and with a movement device for rotating the shear cutting members with a reciprocating rotary motion, with equal angles and in opposite directions; the shear cutting members rotate between a retracted rest position and an advanced cutting position to form a glass gob from at least one thread of molten glass; the movement device is provided with a connecting rod and crank transmission, a rotary motor with a rotor, which drives such transmission, and with a control unit, which controls the rotary motor and is configured so as to rotate the rotor in opposite directions between two stroke-end angular positions, corresponding to the retracted rest position of the shear cutting members.

An apparatus for measuring speed, the length and elongation of a molten glass gob travelling along a defined path includes at least two optical detectors. A mask having at least two openings through which light passes to each of the optical detectors is disposed adjacent the optical detectors. A lens receives light from the moving glass gob and focuses such light through the openings of the mask. Electronics are coupled to each of the optical detectors for determining the speed of the molten glass gob as a function of timing of light sensed at the optical detectors. In exemplary embodiments of the disclosure, the optical detectors is disposed within the image plane of the lens and comprise different portions of a single light sensing device.

Method of filling a mould with a glass gob through an opening of the mould, for forming a glass product in the mould, by using a delivery system for delivering the glass gob to the opening of the mould. The delivery system has an inlet, an outlet, and guiding means for guiding the glass gob through the delivery system. The method includes observing the glass gob, at at least one moment and/or during at least one period after the glass gob has passed the inlet of the delivery system, by using an optical imaging device. The method includes determining a glass gob observation result that includes a glass gob velocity, for predicting a glass distribution of the glass product formed in the mould and/or for controlling a next glass gob.

A method for manufacturing a glass assembly comprises the steps: lowering of a dip pipe that gas may flow through vertically to the surface of a glass melt; determining when the surface of the glass melt is encountered by the dip pipe end showing towards the glass melt by detecting an increase of the gas pressure found inside the dip pipe; continued lowering of the dip pipe until a predetermined depth of entry of the dip pipe end showing towards the glass melt is reached; obtaining a predetermined pressure inside the dip pipe while the dip pipe first stays at the given immersion depth for the given duration and after the predetermined duration is completed, is lifted with a given speed vertically to the surface of the glass melt, thus creating a gas bubble in the glass melt whose walls are attached to the end of the dip pipe; continued lifting of the dip pipe vertically to the surface of the glass melt until the gas bubble is separated from the glass melt, with the wall of the gas bubble remaining at the dip pipe end as a closing film; and setting, especially controlling and/or adjusting of the pressure inside the dip pipe based on the geometry of the film closing the end of the dip pipe as determined by an image capturing device.

Method for removing bubbles from a molten substrate. The molten substrate from a furnace passes through a downtube to reach additional manufacturing tools, such as an extrusion bushing. One or more ultrasonic sensors are arranged along the downtube. The ultrasonic sensor(s) transmit ultrasonic energy into the molten substrate and measure a characteristic of the ultrasonic energy, such as a propagation time for the ultrasonic energy to be reflected back to the ultrasonic sensor(s). A bubble is detected when a change in the Characteristic of the ultrasonic energy is detected. When a bubble is detected, flow through the downtube is diverted to a duct to remove a slug of molten substrate that includes the bubble.

A device for flowing molten glass suitable for installation on a glass melting furnace, including: a flow channel including an outlet of given diameter; and a device for regulating flow of molten glass at an outlet of the flow channel, including: a removable plate including a through-orifice with an area smaller than an area of the outlet of the flow channel; and a movable shuttering mechanism configured to adjustably shutter the outlet of the flow channel or the through-orifice of the removable plate. The device allows a single furnace to be used for various types of glasses having very different viscosities.

A method includes observing a molten glass gob discharged from a transport cup and adjusting a fluid flow parameter of the transport cup based on an observed characteristic of the discharged glass gob.