The present invention relates to mold cooling method and system for a glass container forming machine that includes at least one mold holder including mold halves that are movable between a closed mold position for forming the glass article and an open mold position for releasing said article, each of the mold halves having axial passages for cooling each of the mold halves. A support structure having a fixed upper support section and a movable support section. Means for providing a cooling flow are coupled in coincidence with a series of openings in the movable support section. A cooling flow distributor located above the movable support section, the cooling flow distributor having a lower section in coincidence with each of the openings of the movable support section for the passage of the cooling flow and, a upper section in coincidence with each of the axial passages of each of the halves of each mold, the cooling flow distributor being movable between the closed mold position and the open mold position.

A mold and neck ring cooling system for a glass molding machine is characterized by a cooling air guide, in which separate and in particular independently switchable air guides for a neck ring cooling section- and a mold cooling section are provided. Here, a cooling piece serving the cooling air feed in the mold is connected to a station box via a cooling channel which is articulated on both sides and slidably connected on one side for length compensation, wherein the height position of the cooling piece is constant relative to the station box. A cooling structure intended for the neck ring cooling section is adjustable in its height in relation to the station box by means of a drive. All valves and bearing points are arranged protected against an environmental influence of a glassworks containing abrasive substances.

A mold and neck ring cooling system for a glass molding machine is characterized by a cooling air guide, in which separate and in particular independently switchable air guides for a neck ring cooling sectionand a mold cooling section are provided. Here, a cooling piece serving the cooling air feed in the mold is connected to a station box via a cooling channel which is articulated on both sides and slidably connected on one side for length compensation, wherein the height position of the cooling piece is constant relative to the station box. A cooling structure intended for the neck ring cooling section is adjustable in its height in relation to the station box by means of a drive. All valves and bearing points are arranged protected against an environmental influence of a glassworks containing abrasive substances.

The present invention relates to mold cooling method and system for a glass container forming machine that includes at least one mold holder including mold halves that are movable between a closed mold position for forming the glass article and an open mold position for releasing said article, each of the mold halves having axial passages for cooling each of the mold halves. A support structure having a fixed upper support section and a movable support section. Means for providing a cooling flow are coupled in coincidence with a series of openings in the movable support section. A cooling flow distributor located above the movable support section, the cooling flow distributor having a lower section in coincidence with each of the openings of the movable support section for the passage of the cooling flow and, a upper section in coincidence with each of the axial passages of each of the halves of each mold, the cooling flow distributor being movable between the closed mold position and the open mold position.

A closing mechanism for the mold halves of an I.S. machine, including two yoke-like mold holders mounted on parallel guides and movable between a closed position and an open position by means of a drive. A spindle transmission is provided laterally to at least one guide, the spindle transmission including a threaded spindle that is connected to the drive via a transmission and is in engagement with two threaded sleeves, each of which is connected to one of the two mold holders via two threaded sections running in opposite directions. By means of the drive, a servomotor, the opening and closing movement of the mold holders is carried out. Two pneumatically actuated piston-cylinder units are provided in order to apply the clamping force required between the mold holders or the mold halves in the closed position.

The invention relates to a closing mechanism for the mold halves (5) of an I.S. machine, consisting of two yoke-like mold holders (3, 4) which are mounted on parallel guides (1, 2) and can be moved along said guides between a closed position and an open position by means of a drive. A spindle transmission (13) is provided laterally to the guide (1) so as to extend parallel to said guide, consisting of a threaded spindle that is connected to the drive via a transmission (15) and is in engagement with two threaded sleeves, each of which is connected to one of the two mold holders (3, 4), via two threaded sections running in opposite directions for the purpose of producing an opening or closing movement of the mold holders (3, 4). By means of the drive, a servomotor, the opening and closing movement of the mold holders (3, 4) is carried out. Two pneumatically actuated piston-cylinder units (22) are provided in order to apply the clamping force required between the mold holders (3, 4) or the mold halves (5) in the closed position, said units likewise being connected to the mold holders (3, 4) via an interposed toggle lever mechanism. A more structurally simple and reliable design is provided for the closing mechanism, said design also being free of thermal stresses on the basis of a coolant network integrated at least into the mold holders (3, 4).

In a glass product forming machine having molds 1A and 1B each composed of a pair of split molds 11 and 12, and a mold cooling device X for cooling the molds 1A and 1B to control the temperatures thereof, in order to prevent the occurrence of a defect such as deformation or cracks in a formed article due to a temperature difference between the split molds 11 and 12, the mold cooling device X is configured to include: cooling mechanisms 3R and 3L provided to the respective split molds, the cooling mechanisms each individually applying cooling air to each of the split molds 11 and 12 of the molds 1A and 1B; valve mechanisms 30R and 30L for individually opening and closing each of paths for introducing cooling air to the respective cooling mechanisms 3R and 3L; temperature detection means for detecting the temperature of at least one of the split molds; and a temperature control device 9 for generating and outputting control signals for controlling the opening and closing operations of the respective valve mechanisms 30R and 30L on the basis of the detected temperature value by the temperature detection means.

A glass forming machine includes a blank mold hanger and a blank mold. The blank mold hanger includes a blank mold hanger half that supports a blank mold half and provides cooling fluid to at least one axial cooling channel defined in the blank mold half. The blank mold hanger half defines at least one cooling fluid outlet, which is in fluidic communication with the at least one axial cooling channel of the blank mold half. The blank mold hanger half additionally includes at least one flow control valve that is remotely controllable and configured to selectively adjust a flow of cooling fluid through the at least one axial cooling channel of the blank mold half. A method of cooling a blank mold is also described.