This disclosure describes substrate(s) formed with a three-dimensional (3D) feature thereon, and method(s) of printing the same. One method includes identifying a plurality of locations on a substrate surface where the three-dimensional feature will be formed, determining a height value of the three-dimensional feature at each location, assigning a grayscale value to each location based on the height value, and applying ink to the substrate surface at each location according to the assigned grayscale value.

This disclosure describes substrate(s) formed with a three-dimensional (3D) feature thereon, and method(s) of printing the same. One method includes identifying a plurality of locations on a substrate surface where the three-dimensional feature will be formed, determining a height value of the three-dimensional feature at each location, assigning a grayscale value to each location based on the height value, and applying ink to the substrate surface at each location according to the assigned grayscale value.

The invention refers to an anomaly processing system suitable for processing a malfunction of a glass forming machine, comprising a malfunction detection unit for detecting a malfunction of the glass forming machine; a presence detection unit for detecting the presence of an operator; and in the event of a detected malfunction, a control unit for controlling the glass forming machine. The anomaly processing system is configured such that, in the event of a malfunction, the control of the glass forming machine by the anomaly processing system is dependent on whether the presence of an operator is detected.

The invention refers to an anomaly processing system suitable for processing a malfunction of a glass forming machine, comprising a malfunction detection unit for detecting a malfunction of the glass forming machine; a presence detection unit for detecting the presence of an operator; and in the event of a detected malfunction, a control unit for controlling the glass forming machine. The anomaly processing system is configured such that, in the event of a malfunction, the control of the glass forming machine by the anomaly processing system is dependent on whether the presence of an operator is detected.

This disclosure describes substrate(s) having a three-dimensional (3D) feature formed thereon and methods of forming the features. One method involves applying a first layer of UV-curable material on a surface of the glass container around a circumference of the container and curing the first layer of UV-curable material to produce a first cured material layer that forms at least a portion of a first 3D feature. The method further comprises applying a second layer of UV-curable material on the surface of the glass container, spaced apart from the first 3D feature, around the circumference of the container, and curing the second layer of UV-curable material to produce a second cured material layer that forms at least a portion of a second 3D feature. The portion of the glass container between the first and second 3D features has a circumference less than that of the first or second 3D features.

This disclosure describes substrate(s) having a three-dimensional (3D) feature formed thereon and methods of forming the features. One method involves applying a first layer of UV-curable material on a surface of the glass container around a circumference of the container and curing the first layer of UV-curable material to produce a first cured material layer that forms at least a portion of a first 3D feature. The method further comprises applying a second layer of UV-curable material on the surface of the glass container, spaced apart from the first 3D feature, around the circumference of the container, and curing the second layer of UV-curable material to produce a second cured material layer that forms at least a portion of a second 3D feature. The portion of the glass container between the first and second 3D features has a circumference less than that of the first or second 3D features.

A method for producing a hollow glass product by an I.S. machine, said method being a press-blow or blow-blow method and implementing at least one parison mould and one blow mould, said method comprising the lubrication of said parison mould, the lubrication comprising spraying via a nozzle, said nozzle being carried by the arm of a mobile robot movable along the parison mould side of the I.S. machine, characterised in that said mobile robot is configured to bring said nozzle into the lubricating position after the glass gob has left the parison mould for the blow mould; spray the lubricant into said parison mould; withdraw said nozzle from the lubricating position before the transfer arm returns between the two half-moulds of the parison mould.

A method for producing a hollow glass product by an I.S. machine, said method being a press-blow or blow-blow method and implementing at least one parison mould and one blow mould, said method comprising the lubrication of said parison mould, the lubrication comprising spraying via a nozzle, said nozzle being carried by the arm of a mobile robot movable along the parison mould side of the I.S. machine, characterised in that said mobile robot is configured to bring said nozzle into the lubricating position after the glass gob has left the parison mould for the blow mould; spray the lubricant into said parison mould; withdraw said nozzle from the lubricating position before the transfer arm returns between the two half-moulds of the parison mould.

A method of manufacturing a glass container includes melting a batch material, which contains cullet, to produce molten glass having a soda-lime-silica chemical composition. A flow of molten glass is delivered to a forehearth and conditioned within the forehearth, which includes reducing a temperature of the flow of molten glass such that the temperature of the flow of molten glass at an outlet of the forehearth is less than the temperature of the flow of molten glass at an inlet of the forehearth. Additionally, the method involves introducing colored cullet into the flow of molten glass, which produces colored striations within the glass flow. An output of conditioned molten glass is discharged from the forehearth and a glass container is formed from the conditioned molten glass. The glass container has a glass substrate that includes random streaks of color.

A method of manufacturing a glass container includes melting a batch material, which contains cullet, to produce molten glass having a soda-lime-silica chemical composition. A flow of molten glass is delivered to a forehearth and conditioned within the forehearth, which includes reducing a temperature of the flow of molten glass such that the temperature of the flow of molten glass at an outlet of the forehearth is less than the temperature of the flow of molten glass at an inlet of the forehearth. Additionally, the method involves introducing colored cullet into the flow of molten glass, which produces colored striations within the glass flow. An output of conditioned molten glass is discharged from the forehearth and a glass container is formed from the conditioned molten glass. The glass container has a glass substrate that includes random streaks of color.