The invention refers to a glass forming machine which includes a blank station for forming a parison (14) from a gob of molten glass (9) and a blow station for forming the parison (14) into a container (26) and an invert mechanism (16) which can move a neck ring (5) from the blank station to the blow station by a rotary motion and which further includes a swab robot and a control device for the swab robot, wherein the control device is set up so that the swab robot can swab and thus swab the neck ring (5) when the neck ring (5) is in an intermediate position between the blank station and the blow station. Defects in the production of bottles can thus be avoided.

The invention refers to a glass forming machine which includes a blank station for forming a parison (14) from a gob of molten glass (9) and a blow station for forming the parison (14) into a container (26) and an invert mechanism (16) which can move a neck ring (5) from the blank station to the blow station by a rotary motion and which further includes a swab robot and a control device for the swab robot, wherein the control device is set up so that the swab robot can swab and thus swab the neck ring (5) when the neck ring (5) is in an intermediate position between the blank station and the blow station. Defects in the production of bottles can thus be avoided.

A valve assembly (1) which is intended for differentiated individual control of the movement mechanisms of an IS machine and can therefore be used in a modular manner consists of a valve support (2′) and a head part (22) which supports two pilot control valves (3, 5), two safety valves (4, 6) and two switching valves as one assembly. By way of actuation of the safety valves (4, 6), the feed of control air to the switching valves can be interrupted, which switching valves are assigned, for example, to the opening movement and the closing movement, respectively, of a closing cylinder which is assigned to a preform. The valve assembly has interfaces for connection of control and operating air and for electric connection to a machine controller. If required, the assembly which is designed in this way makes it possible to interrupt the control air in a differentiated way which is related to an individual track, in addition to simple assembly and dismantling.

A takeout mechanism for glassware forming machines includes: a supporting structure; an oscillating arm connected by a first end, in pivot form, to a movement transmission system to move the oscillating arm with an angular movement; and, a takeout tong head coupled at a second end of the oscillating arm. The oscillating arm comprises a hollow housing, a first fixed shaft coupled at the first end of the housing; first cam means coupled to the first fixed axis; a second rotating shaft coupled at the second end of the housing, spaced parallel to the first shaft, one end being coupled to the takeout tong head; second cam means coupled to the second rotating axis; and linkage means pivotally connecting the first cam means of said first fixed axis and said second cam means of said second rotating axis.

A takeout mechanism for glassware forming machines includes: a supporting structure; an oscillating arm connected by a first end, in pivot form, to a movement transmission system to move the oscillating arm with an angular movement; and, a takeout tong head coupled at a second end of the oscillating arm. The oscillating arm comprises a hollow housing, a first fixed shaft coupled at the first end of the housing; first cam means coupled to the first fixed axis; a second rotating shaft coupled at the second end of the housing, spaced parallel to the first shaft, one end being coupled to the takeout tong head; second cam means coupled to the second rotating axis; and linkage means pivotally connecting the first cam means of said first fixed axis and said second cam means of said second rotating axis.

Methods and systems for controlling vertical glass distribution are provided. A traversing pyrometer periodically measures a parison actual temperature after the parisons exit a blank mold. The thermal camera takes a thermal image of each glass container after the glass container exits the blow mold. A vertical glass signature extraction module extracts a vertical glass distribution signature. A parison temperature estimator determines a parison estimated temperature for each vertical glass distribution signature obtained based on the vertical glass distribution signature, a most recently measured parison actual temperature and a parison stretch time. A parison temperature summer compares the parison estimated temperature to a parison set point temperature to determine a parison temperature error. A parison temperature control controls a blank mold contact time based on the parison temperature error.

Methods and systems for controlling vertical glass distribution are provided. A traversing pyrometer periodically measures a parison actual temperature after the parisons exit a blank mold. The thermal camera takes a thermal image of each glass container after the glass container exits the blow mold. A vertical glass signature extraction module extracts a vertical glass distribution signature. A parison temperature estimator determines a parison estimated temperature for each vertical glass distribution signature obtained based on the vertical glass distribution signature, a most recently measured parison actual temperature and a parison stretch time. A parison temperature summer compares the parison estimated temperature to a parison set point temperature to determine a parison temperature error. A parison temperature control controls a blank mold contact time based on the parison temperature error.

A glassware manufacturing system, waste handling system, and method are disclosed. The glassware manufacturing system, in accordance with one aspect of the disclosure, comprises an architectural installation having a forming floor and no basement beneath the forming floor; a glassware forming machine carried on the forming floor; a molten glass feeder configured to provide molten glass to the glassware forming machine; and a glassware manufacturing waste handling system including a sump pit in the forming floor, and a waste liquid trench substantially surrounding the glassware forming machine and flowing to the sump pit. Also, a cullet material handler and/or a molten waste glass sluice may be configured to receive molten glass and unused molten glass streams from the molten glass feeder and hot glassware rejects from the glassware forming machine.

Methods and systems for controlling vertical glass distribution are provided. A traversing pyrometer periodically measures a parison actual temperature after the parisons exit a blank mold. The thermal camera takes a thermal image of each glass container after the glass container exits the blow mold. A vertical glass signature extraction module extracts a vertical glass distribution signature. A parison temperature estimator determines a parison estimated temperature for each vertical glass distribution signature obtained based on the vertical glass distribution signature, a most recently measured parison actual temperature and a parison stretch time. A parison temperature summer compares the parison estimated temperature to a parison set point temperature to determine a parison temperature error. A parison temperature control controls a blank mold contact time based on the parison temperature error.

Methods and systems for controlling vertical glass distribution are provided. A traversing pyrometer periodically measures a parison actual temperature after the parisons exit a blank mold. The thermal camera takes a thermal image of each glass container after the glass container exits the blow mold. A vertical glass signature extraction module extracts a vertical glass distribution signature. A parison temperature estimator determines a parison estimated temperature for each vertical glass distribution signature obtained based on the vertical glass distribution signature, a most recently measured parison actual temperature and a parison stretch time. A parison temperature summer compares the parison estimated temperature to a parison set point temperature to determine a parison temperature error. A parison temperature control controls a blank mold contact time based on the parison temperature error.