Closures with a tamper evidence feature that is reshaped to connect it to the container neck are disclosed. Methods and systems for carrying out the methods, and to mold stacks for making the closures are also disclosed. The tamper evidence feature can be a band, a portion of a cylindrical skirt or a panel formed in the cylindrical skirt. The application of heat may deform the band inwardly to create a lip for engaging a flange on the container neck, or it may weld the tamper evidence feature to the flange
B65B 51/22 - Applying or generating heat or pressure or combinations thereof by friction or ultrasonic or high-frequency electrical means
B23K 26/352 - Working by laser beam, e.g. welding, cutting or boring for surface treatment
B65B 7/28 - Closing semi-rigid or rigid containers or receptacles not deformed by, or not taking-up shape of, contents, e.g. boxes or cartons by applying separate preformed closures, e.g. lids, covers
B65B 61/00 - Auxiliary devices, not otherwise provided for, for operating on sheets, blanks, webs, binding material, containers or packages
B65D 41/34 - Threaded or like caps or cap-like covers
Closures with a tamper evidence feature that is reshaped to connect it to the container neck are disclosed. Methods and systems for carrying out the methods, and to mold stacks for making the closures are also disclosed. The tamper evidence feature can be a band, a portion of a cylindrical skirt or a panel formed in the cylindrical skirt. The application of heat may deform the band inwardly to create a lip for engaging a flange on the container neck, or it may weld the tamper evidence feature to the flange
B65B 7/28 - Closing semi-rigid or rigid containers or receptacles not deformed by, or not taking-up shape of, contents, e.g. boxes or cartons by applying separate preformed closures, e.g. lids, covers
B65B 51/10 - Applying or generating heat or pressure or combinations thereof
A mold assembly (100) for making tubular articles. The mold assembly includes a core plate (210), core inserts (230) mounted to the core plate (210) by fasteners (B), a cavity plate (410) with holes (413) through its thickness and cavity inserts (420) mounted to the cavity plate (410). Each core insert (230) has a molding surface (234a) and an engagement taper (233) between the molding surface and its mounting surface (236). At least part of the engagement taper (233) is located closer to the mounting surface (236) than it is to the molding surface (234a) for inhibiting the core insert (230) from tipping when the engagement taper (233) is engaged to move or slide the core insert (230) along the core plate (210). The assembly (100) has an assembled configuration, in which the core plate (210) is mounted to the a cavity plate (410), such that each core insert (230) describes with a respective cavity insert (420) a hollow body and each cavity plate hole (413) is aligned with a respective core insert fastener (B) for allowing a tool to be inserted therethrough to access the core insert fastener (B).
Closures with a tamper evidence feature that is reshaped to connect it to the container neck are disclosed. Methods and systems for carrying out the methods, and to mold stacks for making the closures are also disclosed. The tamper evidence feature can be a band, a portion of a cylindrical skirt or a panel formed in the cylindrical skirt. The application of heat may deform the band inwardly to create a lip for engaging a flange on the container neck, or it may weld the tamper evidence feature to the flange
Closures with a tamper evidence feature that is reshaped to connect it to the container neck are disclosed. Methods and systems for carrying out the methods, and to mold stacks for making the closures are also disclosed. The tamper evidence feature can be a band, a portion of a cylindrical skirt or a panel formed in the cylindrical skirt. The application of heat may deform the band inwardly to create a lip for engaging a flange on the container neck, or it may weld the tamper evidence feature to the flange
Closures with a tamper evidence feature that is reshaped to connect it to the container neck are disclosed. Methods and systems for carrying out the methods, and to mold stacks for making the closures are also disclosed. The tamper evidence feature can be a band, a portion of a cylindrical skirt or a panel formed in the cylindrical skirt. The application of heat may deform the band inwardly to create a lip for engaging a flange on the container neck, or it may weld the tamper evidence feature to the flange
Closures (1) with a tamper evidence feature (5) that is reshaped to connect it to the container neck (2) are disclosed. Methods and systems (8) for carrying out the methods, and to mold stacks (102) for making the closures are also disclosed. The tamper evidence feature can be a band (5), a portion (505) of a cylindrical skirt (504) or a panel (705) formed in the cylindrical skirt (704). The application of heat may deform the band (5) inwardly to create a lip (52) for engaging a flange (20) on the container neck (2), or it may weld the tamper evidence feature (305) to the flange (220).
B65B 7/28 - Closing semi-rigid or rigid containers or receptacles not deformed by, or not taking-up shape of, contents, e.g. boxes or cartons by applying separate preformed closures, e.g. lids, covers
B29C 45/17 - Component parts, details or accessoriesAuxiliary operations
B65D 41/34 - Threaded or like caps or cap-like covers
B65D 55/08 - Annular elements encircling container necks
A mold assembly (100) for molding tethered and non-tethered closures (106, 206), which includes a core (112, 114) with recesses (101a, 101b, 101c) in its circumferential surface (114a) that describe cams (107a, 107b, 107c, 207a, 207b, 207c) for engaging a flange of a neck of a container to which the closure is to be installed. The mold assembly has a first configuration, in which the core and a first set of slides (122A, 122B) together describe a closure (106) having a completely removable tamper evidence band (107), and a second configuration, in which the same core and a second set of slides (222A, 222B) together describe a closure (206) with a tamper evidence band (207) that is retained by tethers (209). The cams (107a, 107b, 107c, 207a, 207b, 207c) of both closures (106, 206) are at different axial locations for accommodating the tethers in the second configuration.
B29C 43/02 - Compression moulding, i.e. applying external pressure to flow the moulding materialApparatus therefor of articles of definite length, i.e. discrete articles
B29C 45/14 - Injection moulding, i.e. forcing the required volume of moulding material through a nozzle into a closed mouldApparatus therefor incorporating preformed parts or layers, e.g. injection moulding around inserts or for coating articles
B65D 41/34 - Threaded or like caps or cap-like covers
A mold stack (104, 204, 304, 404, 504) for molding a preform (P) that includes a cavity insert (131, 231, 331, 431, 531), a split mold insert (123, 223, 323, 423, 523) and an interface (140, 240, 340, 440, 540) therebetween. The cavity insert has a molding surface (135, 235, 335, 435, 535) describing part of a body of the preform. The split mold insert has a molding surface (124, 224, 324, 424, 524) describing part of the body and a radial flange of the preform. The interface includes a non-mating portion (141, 241, 341, 441, 541) that surrounds and extends from the molding surfaces and a mating portion (142, 242, 342, 442, 542) that surrounds the non-mating portion. The non-mating portion describes a gap (G) between the cavity and split mold inserts when a clamp force is transmitted across the mating portion when the mold stack is in a molding configuration.
An injection molding apparatus comprises a support base and a mold carrier removably mounted to the support base. The mold carrier includes a mounting plate with attachment features for engaging the support base. A mold with two mold plates is slidably mounted to the mounting plate. A clamp is operable to move the plates between open and closed positions. In the closed position, the plates abut one another. In the open position, the plates are spaced apart for removing molded articles.
A closure assembly for a carton, which includes a closure, a neck to which the closure is mounted and a cutter received within the neck for piercing a foil of the carton. The closure includes a retaining ring for securement around the container neck below an annular flange of the neck, a lid pivotally connected to the retaining ring and a tamper evidence band frangibly connected to the retaining ring. The closure engages the cutter when it is rotated, which causes the cutter to pierce the foil of the carton as the closure is opened. The tamper evidence band has a rotational stop which engages a rotational stop of the container neck to separate the tamper evidence band from the retaining ring on first rotation of the closure in the opening direction.
B65D 41/34 - Threaded or like caps or cap-like covers
B65D 51/22 - Caps, lids, or covers co-operating with an inner closure arranged to be opened by piercing, cutting, or tearing having means for piercing, cutting, or tearing the inner closure
A closure device for a container having a neck including an annular flange, the closure device comprising: a cap body; a tamper evident (TE) band positioned below the annular flange when assembled in the container; a first hinge and a second hinge defined on the cap body; a leash connected to the TE band, the first hinge and the second hinge; the leash allowing for the cap body to be separated from the TE band during opening, but to remain connected thereto via the leash; a tongue protruding from the cap body between the first and second hinges; when the cap body is actuated from a closed configuration relative to the neck to a fully open position: the leash is configured to retain the cap body to the TE band; an interaction of the tongue and the neck is configured to retain the cap body in the fully open position.
B65D 55/16 - Devices preventing loss of removable closure members
B65D 41/34 - Threaded or like caps or cap-like covers
B65D 47/08 - Closures with discharging devices other than pumps with pouring spouts or tubesClosures with discharging devices other than pumps with discharge nozzles or passages having articulated or hinged closures
The invention relates to a preform conditioning system (100, 200, 300), which includes a heating device (101, 201, 301), a preform holder (102, 202, 302) for holding a preform (P) to be irradiated by electromagnetic radiation (ER) from the heating device and a screen (103, 203, 303) shaped and configured to at least partially surround a preform (P) held by the preform holder (102, 202, 302) for selectively screening part of the preform (P) from electromagnetic radiation (ER). The position of the screen (103, 203, 303) is adjustable relative to each of the heating device (101, 201, 301) and a preform (P) held by the preform holder (102, 202, 302).
A molded article suitable for subsequent blow-molding into a final-shaped container. The article includes a neck portion; a gate portion; and a body portion extending between the neck portion and the gate portion, at least a majority of the body portion having an overall shape which is symmetric about a body axis extending longitudinally through a center of the body portion. The body portion includes an inner exterior layer and an outer exterior layer of a first polymeric material; and a core layer of a second polymeric material disposed between the inner exterior layer and the outer exterior layer. A radial thickness or a material of the core layer is selectively varied to govern non-uniform blow molding of the molded article into the final-shaped container.
A method of heating plastic blanks for molding comprises, for each blank in a sequence of blanks of different types, determining a heating requirement corresponding to characteristics of the blank a molding process to be applied and heating each blank according to its heating requirement. A microwave field is generated having a defined heating rate, and the blank is placed in the microwave field for a period of time equal to the heating duration, such that the heating duration and the heating rate correspond to the heating requirement.
A molding system including a molding machine, a vision system and a processor is disclosed. The molding machine, which is fpr producing a plurality of molded articles, has a additive device for adjusting a color of the plurality of molded articles. The vision system is for detecting a color of each of at least two molded articles of the plurality of molded articles. The processor, which is operatively connected to the molding machine and to the vision system, is configured to analyze data generated by the vision system, and in response to a difference between (i) an average of a detected color of at least two molded articles and (ii) a desired color being different from a predetermined value, the processor is configured to control the additive device for adjusting the color of the plurality of molded articles. Methods for optically inspecting molded articles are also disclosed.
A molding apparatus for molding a closure device for a container. The closure device may be tethered to the container, and may open and close via a hinged articulation. The closure device includes a cylindrical body comprising hinge-connecting areas with pockets formed in the interior wall and defining an inner surface of the hinge-connecting areas, and hinges extending downwardly from the hinge-connecting areas and positioned at or below a bottom edge of the cylindrical body. The molding apparatus comprises a cavity insert component and a core component that cooperate to form mold surfaces to mold the closure device such that hinges are located below the cap area of the closure device, and hinge-connecting areas formed by projections in the core mold component and recesses in the cavity mold component are located within the cap area are flanked by membranous areas.
In one aspect, a method of coinjection molding a multilayer article using a coinjection nozzle having inner outlet, an outer outlet, and an intermediate outlet between the inner and outer outlets is provided. A stream of surface layer material is injected into a mold cavity from the intermediate outlet. With the injection ongoing, two streams of internal layer material are injected from the inner and outer outlets of the coinjection nozzle respectively. The two streams sandwich the stream of surface layer material and flow behind a melt front of the surface layer material. The sandwiched stream of surface layer material continues to supply the melt front with surface layer material at least until the melt front nears a distal end of the mold cavity. The resultant article is substantially or entirely encapsulated by a skin of the surface layer material and contains a high proportion of internal layer material.
B32B 27/08 - Layered products essentially comprising synthetic resin as the main or only constituent of a layer next to another layer of a specific substance of synthetic resin of a different kind
A system for marking a product is provided. The system comprises: a first laser configured to emit a first beam along a first optical axis, the first beam having a first beam energy density when focused; and a second laser configured to emit a second beam along a second optical axis, the second beam having a second beam energy density when focused; and a beam modulator component configured to adjust at least one of: an angle between the first optical axis of the first beam and the second optical axis of the second beam, a first focusing distance of the first beam, and a second focusing distance of the second beam, such that the first beam energy density and the second beam energy density combined is greater than the threshold energy density sufficient to create the marking.
A system for marking a product is provided. The product includes a markable region having: at least one first region of a photoactivatable material, at a first depth in a wall of the product, and at least one second region of the photoactivatable material, at a second depth in the wall of the product. The system comprises: a laser configured to emit a beam having a beam energy density above a threshold energy density; a beam modulator component configured to modulate a focusing distance of the beam to: a first focusing distance which is incident on the at least one first region for creating the markings in the at least one first region, and a second focusing distance incident on the at least one second region for creating the markings in the at least one second region.
B41J 2/44 - Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by selective application of radiation to a printing material or impression-transfer material using single radiation source, e.g. lighting beams or shutter arrangements
B23K 26/18 - Working by laser beam, e.g. welding, cutting or boring using absorbing layers on the workpiece, e.g. for marking or protecting purposes
B23K 26/53 - Working by transmitting the laser beam through or within the workpiece for modifying or reforming the material inside the workpiece, e.g. for producing break initiation cracks
B41J 2/455 - Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by selective application of radiation to a printing material or impression-transfer material using arrays of radiation sources using laser arrays
B41J 2/525 - Arrangement for multi-colour printing, not covered by group , e.g. applicable to two or more kinds of printing or marking process
21.
METHODS FOR DETERMINING ZONE TYPES OF HEATING ZONES IN AN INJECTION MOLDING SYSTEM
An injection molding system is disclosed. The injection molding system includes: a hot runner including: a plurality of heaters arranged into one or more defined heating zones within the hot runner; and at least one temperature sensor associated with each heating zone, and a system controller coupled to the plurality of heaters, the system controller being configured to: for each heating zone: determine a first control gain value associated with the heating zone; determine a total heater power of heaters associated with the heating zone; calculate a relative weight associated with the heating zone based on the first control gain value and the total heater power; and determine a zone type associated with the heating zone based on the relative weight.
Methods and apparatus are disclosed for gripping an object with a resilient bladder containing granular material. The bladder has a relaxed state, in which the bladder is deformable. The bladder further has a gripping state, in which negative pressure is applied to the interior of the bladder to compact the granular material. Such compaction stiffens the bladder against deformation. In the gripping state, a gripping force is applied to the object at a concave gripping surface of the bladder.
An injection molding system is disclosed. The injection molding system includes: a mold; a hot runner including: a manifold; one or more injection nozzles coupled to the manifold; a plurality of heaters in thermal contact with the manifold and the one or more injection nozzles, the heaters being arranged into one or more defined heating zones within the hot runner; and at least one temperature sensor associated with each heating zone, and a system controller coupled to the plurality of heaters, the system controller being configured to: for each heating zone: determine a setpoint temperature associated with the heating zone; obtain, via a temperature sensor, measurement of a current local temperature of the heating zone; determine a control gain value associated with the heating zone; and compute a predicted heating time for the heating zone based on the setpoint temperature, the current local temperature, and the control gain value, determine a heating schedule for the hot runner based on the predicted heating times for the heating zones; and operate the plurality of heaters in accordance with the heating schedule.
In one aspect, there is provided an injection molding system configured to operate in a plurality of cycles. The system comprises, amongst other things, a controller that is configured for performing a comparison of a variable pressure setpoint with a target pressure value. The controller is configured to, when the target pressure value is less than the variable pressure setpoint by at least a predetermined lower bound, (i) decrease the variable pressure setpoint to a reduced variable pressure setpoint and (ii) not further decrease the variable pressure setpoint from the reduced variable pressure setpoint until the pump assembly operates for a plurality of stabilizing cycles at the reduced variable pressure setpoint.
In one aspect, an injection unit for an injection molding machine having a hot runner with a sprue comprises a heated melt pipe configured to convey a continuous stream of melt, a shooting pot assembly, and a telescopic melt coupling. The shooting pot assembly is configured to convert the continuous stream of melt from the heated melt pipe into batches for cyclical injection and is translatable between a sprue-engagement position and a sprue-disengagement position. The telescopic melt coupling is configured to convey melt from the heated melt pipe to the shooting pot assembly and has a variable length. The variable length telescopic melt coupling permits translation of the shooting pot assembly, relative to the heated melt pipe, between the sprue-engagement position and the sprue-disengagement position while maintaining a fluid melt interconnection between the heated melt pipe and the shooting pot assembly.
An injection molding system configured to operate in a plurality of cycles includes, amongst other things, a controller that is configured for performing a comparison of a variable pressure setpoint with a target pressure value. The controller is configured to, when the target pressure value is less than the variable pressure setpoint by at least a predetermined lower bound, (i) decrease the variable pressure setpoint to a reduced variable pressure setpoint and (ii) not further decrease the variable pressure setpoint from the reduced variable pressure setpoint until the pump assembly operates for a plurality of stabilizing cycles at the reduced variable pressure setpoint.
A mold assembly (101) for a valve-gated injection mold (191) configured to mitigate tearing along the vestige of a molded part. The assembly (101) includes a gate insert (131) with a nozzle seat (111) which receives a valve-gate injection nozzle assembly (110), a mold cavity portion (132) describing part of a mold cavity, a connecting passageway (124) between the nozzle seat (111) and the mold cavity portion (132) and a vestige forming portion (135) between the connecting passageway (124) and the mold cavity portion (132). An end portion (133) of a valve member (118) of the valve-gate injection nozzle assembly (110) cooperates with a sealing portion (125) of the connecting passageway (124) when the valve member (118) is in a closed position. The vestige forming portion (135) is wider than the sealing portion (125), providing a step (171) having a radial dimension (R2) that is greater than an axial length (L2) of the vestige forming portion (135).
A mold assembly (101) for a valve-gated injection mold (191) configured to mitigate tearing along the vestige of a molded part. The assembly (101) includes a gate insert (131) with a nozzle seat (111) which receives a valve-gate injection nozzle assembly (110), a mold cavity portion (132) describing part of a mold cavity, a connecting passageway (124) between the nozzle seat (111) and the mold cavity portion (132) and a vestige forming portion (135) between the connecting passageway (124) and the mold cavity portion (132). An end portion (133) of a valve member (118) of the valve-gate injection nozzle assembly (110) cooperates with a sealing portion (125) of the connecting passageway (124) when the valve member (118) is in a closed position. The vestige forming portion (135) is wider than the sealing portion (125), providing a step (171) having a radial dimension (R2) that is greater than an axial length (L2) of the vestige forming portion (135).
09 - Scientific and electric apparatus and instruments
37 - Construction and mining; installation and repair services
42 - Scientific, technological and industrial services, research and design
Goods & Services
Injection molding machines and parts and fittings therefor;
replacement parts for injection molding machinery, and
accessories thereof, product handling equipment namely,
conveyors, stackers, sorters, packers, cranes, automated
lifting and clamping devices to lift and clamp injection
molded parts. Computers with firmware and a human machine interface for
controlling the operation of injection molding machines. Refurbishment, maintenance, repair of injection molding
machines, equipment and related components thereof, namely
steel molds used to produce plastic parts, product handling
equipment namely, conveyors, stackers, sorters, packers,
cranes, automated lifting and clamping devices to lift and
clamp injection molded parts, computers with firmware and a
human machine interface for controlling the operation of
injection molding machines, robots for removing molded
plastic parts from an industrial steel mold. Providing engineering and technical support on the operation
and maintenance of injection molding machinery, equipment
and related components thereof, namely steel molds used to
produce plastic parts, product handling equipment namely,
conveyors, stackers, sorters, packers, cranes, automated
lifting and clamping devices to lift and clamp injection
molded parts, computers with firmware and a human machine
interface for controlling the operation of injection molding
machines, robots for removing molded plastic parts from an
industrial steel mold.
30.
METHOD OF IMPROVING SHOT REPEATABILITY IN MULTILAYER RECIPROCATING SCREW INJECTION MOLDING MACHINES
In one aspect there is disclosed a method of improving shot repeatability in a multilayer reciprocating screw injection molding apparatus by preventing pressure communication or “cross-talk” between melt channels. In the first aspect an outlet nozzle valve is closed prior to closing a check valve within an injection unit of the multilayer reciprocating screw injection molding apparatus. In another aspect there is disclosed a method of improving shot repeatability in a reciprocating screw injection molding apparatus by recording a first position of a screw within the barrel of an injection unit of a reciprocating screw injection molding apparatus, the first position corresponding to a volume of melt within the barrel of the material injection unit. A second position of the screw is then calculated based on the first position, the second position corresponding to a transition position of the screw within the barrel of the injection unit of the reciprocating screw injection molding apparatus.
09 - Scientific and electric apparatus and instruments
37 - Construction and mining; installation and repair services
42 - Scientific, technological and industrial services, research and design
Goods & Services
Injection molding machines and parts and fittings therefor; namely, take-off units, robot transfer mechanisms, injection units, unscrewing attachments, hot runner systems, scrap grinders, conveyors, stackers, sorters, cooling units and injection molds; product handling equipment, namely, conveyors, stackers, sorters, packers, cranes, automated lifting and clamping devices to lift and clamp injection molded parts Computers with recorded firmware therefore for operating systems programs, and a computer interface board for controlling the operation of injection molding machines Refurbishment, maintenance, repair of injection molding machines, equipment and related components thereof, technical information and consultancy related to the maintenance of injection molding equipment, namely, injection units, molds, hot runners systems, all for injection molding systems Engineering services, technical analysis and technical research related to the design, the development and the manufacture of plastic injection molding parts; technical information, studies and consultancy related to the operation programming of injection molding equipment; custom design of molds for the manufacture of plastic products, namely, plastic parts, injection unit, molds hot runners systems, part handling devices, all for injection molding systems
A plastic molding method comprises moving each part of a plurality of parts along a selected one of a plurality of possible paths through dispensing and molding stations of a molding system. A controller tracks an operating state of each station, selects process stations capable of receiving a part for processing; identifies parts capable of processing at the selected process stations, and assigns individual parts to individual process stations.
A molding system and a method for molding articles. The molding system includes a molding machine for producing molded articles and at least one inspection device configured to inspect one or more molded articles and a computing apparatus operatively coupled to the at least one inspection device. The inspection device includes at least one multispectral light source configured to illuminate the at least one molded article; and at least one imaging system configured to collect at least some light reflected and scattered from the at least one molded article, the imaging system including at least one detector configured to detect a plurality of wavelengths in light imaged by the imaging system, the detector being communicatively coupled to the computing apparatus. The inspection device is configured to inspect molded articles between an end of a first molding cycle and prior to a start of a second molding cycle.
A mold assembly (100) for making tubular articles. The mold assembly includes a core plate (210), core inserts (230) mounted to the core plate (210) by fasteners (B), a cavity plate (410) with holes (413) through its thickness and cavity inserts (420) mounted to the cavity plate (410). Each core insert (230) has a molding surface (234a) and an engagement taper (233) between the molding surface and its mounting surface (236). At least part of the engagement taper (233) is located closer to the mounting surface (236) than it is to the molding surface (234a) for inhibiting the core insert (230) from tipping when the engagement taper (233) is engaged to move or slide the core insert (230) along the core plate (210). The assembly (100) has an assembled configuration, in which the core plate (210) is mounted to the a cavity plate (410), such that each core insert (230) describes with a respective cavity insert (420) a hollow body and each cavity plate hole (413) is aligned with a respective core insert fastener (B) for allowing a tool to be inserted therethrough to access the core insert fastener (B).
A mold assembly (100) for making tubular articles. The mold assembly includes a core plate (210), core inserts (230) mounted to the core plate (210) by fasteners (B), a cavity plate (410) with holes (413) through its thickness and cavity inserts (420) mounted to the cavity plate (410). Each core insert (230) has a molding surface (234a) and an engagement taper (233) between the molding surface and its mounting surface (236). At least part of the engagement taper (233) is located closer to the mounting surface (236) than it is to the molding surface (234a) for inhibiting the core insert (230) from tipping when the engagement taper (233) is engaged to move or slide the core insert (230) along the core plate (210). The assembly (100) has an assembled configuration, in which the core plate (210) is mounted to the a cavity plate (410), such that each core insert (230) describes with a respective cavity insert (420) a hollow body and each cavity plate hole (413) is aligned with a respective core insert fastener (B) for allowing a tool to be inserted therethrough to access the core insert fastener (B).
A plastic molding system comprises dispensing stations for dispensing molding material into vessels and shaping stations configured to receive molding material from the dispensing stations. A conveying path extends proximate each of the dispensing and shaping stations, and vessels are movable along the path. A controller is operable to direct movement of the vessels along the path and to define partitions dividing the system into zones, each zone comprising dispensing and shaping stations, the shaping stations of each zone for configured for receiving molding material from the dispensing station of the respective zone. The stations of each zone are positioned along respective contiguous sections of the conveying path.
The invention relates to a mold stack (MS) with a core insert (20) and a gate insert (5) that together describe a closed end (11a, 1 la') of a tubular article (1). The gate insert (5) has a cavity portion (50), a nozzle receiving portion (52) and a passage (53) joining them. The cavity portion (50) has an annular ridge (54) that surrounds and joins it to the passage (53). The ridge (54) has a height (H) that is less than one quarter of a diameter (W4) of the passage (53). The core insert (20) has a truncated end portion aligned with the ridge (54) of the gate insert (5), so that the tubular article (1) has a closed end (11a, 11 a') with an outer surface formed by a truncated dome with a recessed apex (14).
09 - Scientific and electric apparatus and instruments
37 - Construction and mining; installation and repair services
42 - Scientific, technological and industrial services, research and design
Goods & Services
Injection molding machines and parts and fittings therefor;
replacement parts for injection molding machinery, and
accessories thereof, product handling machines namely,
conveyors, stackers, sorters, packers, cranes, automated
lifting and clamping devices to lift and clamp injection
molded parts. Computers with firmware and a human machine interface for
controlling the operation of injection molding machines. Refurbishment, maintenance, repair of injection molding
machine, equipment and related components thereof, namely
steel molds used to produce plastic parts, product handling
equipment namely, conveyors, stackers, sorters, packers,
cranes, automated lifting and clamping devices to lift and
clamp injection molded parts, computers with firmware and a
human machine interface for controlling the operation of
injection molding machines, robots for removing molded
plastic parts from an industrial steel mold. Providing engineering and technical support services on the
operation and maintenance of injection molding machinery,
equipment and related components thereof, namely steel molds
used to produce plastic parts, product handling equipment
namely, conveyors, stackers, sorters, packers, cranes,
automated lifting and clamping devices to lift and clamp
injection molded parts, computers with firmware and a human
machine interface for controlling the operation of injection
molding machines, robots for removing molded plastic parts
from an industrial steel mold.
A closure device for a container neck having a cap which is pivotable between closed open configurations, comprising: a base; an outer wall extending circumferentially around the base; a plug seal extending from the base, at an inner face of the cap, and spaced from the outer wall to define a channel for receiving the container neck and for forming a seal against an inner wall of the container neck when the cap is in the closed configuration; a lifting member extending from the base and positioned radially inwardly from the plug seal, the lifting member being positioned at a pivot-side of the cap and having a contact face at a free end of the lifting member for contacting a top end of the container neck before the top end contacts the plug seal during actuation of the cap from the open configuration to the closed configuration.
B65D 45/18 - Clips, hooks, or clamps, e.g. C-shaped of snap-over type
B65D 41/00 - Caps, e.g. crown caps or crown seals, i.e. members having parts arranged for engagement with the external periphery of a neck or wall defining a pouring opening or discharge apertureProtective cap-like covers for closure members, e.g. decorative covers of metal foil or paper
37 - Construction and mining; installation and repair services
Goods & Services
Injection molding systems; hot runners being parts of
injection molding machines; melt delivery systems being
parts of injection molding machines; components, parts and
fittings for melt delivery systems for use in injection
molding machines; control mechanisms for injection molding
machines for controlling the operation of melt delivery
systems. Refurbishment, maintenance and repair of injection molding
machines, parts and fittings thereof and control mechanisms
for melt delivery systems for injection molding provided by
engineers and technicians.
A closure may have a top wall and a side wall depending from the top wall. A plug seal device may depend from said top wall within the side wall. The plug seal device may have an upper section, a lower section, and a sealing section proximate the boundary between the upper section and the lower section. The sealing section is operable such that when the plug seal device is inserted in an opening to an inner cavity in a container, the sealing section engages with an inner container surface to provide a seal between an inner cavity of the container and the external environment.
B65D 41/32 - Caps or cap-like covers with lines of weakness, tearing-strips, tags, or like opening or removal devices, e.g. to facilitate formation of pouring openings
B65D 39/00 - Closures arranged within necks or pouring openings or in discharge apertures, e.g. stoppers
B65D 51/16 - Closures not otherwise provided for with means for venting air or gas
B65D 41/58 - Caps or cap-like covers combined with stoppers
B65D 41/34 - Threaded or like caps or cap-like covers
B65D 41/04 - Threaded or like caps or cap-like covers secured by rotation
B29C 45/00 - Injection moulding, i.e. forcing the required volume of moulding material through a nozzle into a closed mouldApparatus therefor
B29K 23/00 - Use of polyalkenes as moulding material
B29L 31/56 - Stoppers or lids for bottles, jars, or the like
A closure (1) with a shell (2) for securement to a container neck (11) and a lid (3) pivotally connected to the shell (2) by a pair of hinge elements (6). A hinge line (50) in the side wall (5) delineates a deformable latch (8) having an external grip tab (80) and an internal engaging tab (82) between the grip tab (80) and a top wall (4) of the lid (3). The grip tab (80) extends radially from a side wall (5) of the lid (3) and the engaging tab (82) engages a lip (13) surrounding the mouth of the container neck (11). The deformable latch (8) is configured to deform along the hinge line (50) when an opening force is applied to the grip tab (80), thereby to disengage the engaging tab (82) from the lip (13) of the container neck (11).
09 - Scientific and electric apparatus and instruments
37 - Construction and mining; installation and repair services
42 - Scientific, technological and industrial services, research and design
Goods & Services
(1) Injection molding machines and parts and fittings therefor; replacement parts for injection molding machinery; product handling equipment namely, conveyors, stackers, sorters, packers, cranes.
(2) Computers with firmware and a human machine interface for controlling the operation of injection molding machines. (1) Refurbishment, maintenance, repair of injection molding machines, equipment and related components thereof, namely steel molds used to produce plastic parts, product handling equipment namely, conveyors, stackers, sorters, packers, cranes, automated lifting and clamping devices to lift and clamp injection molded parts, computers with firmware and a human machine interface for controlling the operation of injection molding machines, robots for removing molded plastic parts from an industrial steel mold.
(2) Providing engineering services on the operation and maintenance of injection molding machinery, equipment and related components thereof, namely steel molds used to produce plastic parts, product handling equipment namely, conveyors, stackers, sorters, packers, cranes, automated lifting and clamping devices to lift and clamp injection molded parts, computers with firmware and a human machine interface for controlling the operation of injection molding machines, robots for removing molded plastic parts from an industrial steel mold; technical support services, namely troubleshooting on the operation of injection molding machinery and equipment.
An injection molding system is disclosed herein that may include a manifold that may have a manifold melt channel for receiving melted resin, a nozzle having a nozzle melt channel for receiving the melted resin from the manifold melt channel and delivering the melted resin to a mold cavity via a mold gate. In other examples, a valve pin may extend through at least a portion of the nozzle melt channel such that a forward end of the valve pin may be seatable within the mold gate. In certain examples, the injection molding system may include one or more drop plate, each of which defines walls of a cylinder within which a piston reciprocates, and each which may contain cooling circuits and pressurized circuits for opening and closing the piston. With regard to injection molding system containing multiple drop plates, each drop plate is independent of the other drop plates, and each drop plate is dedicated to a single nozzle assembly. In other examples, the drop plates may house a valve pin coupling system configured to permit movement of a valve pin in a lateral direction independent from a lateral position of the piston.
09 - Scientific and electric apparatus and instruments
37 - Construction and mining; installation and repair services
42 - Scientific, technological and industrial services, research and design
Goods & Services
Injection molding machines and parts and fittings therefor, namely, take-off units, robot transfer mechanisms, injection units, unscrewing attachments, hot runner systems, scrap grinders, conveyors, stackers, sorters, cooling units and injection molds; product handling equipment, namely, conveyors, stackers, sorters, packers, cranes, automated lifting and clamping devices to lift and clamp injection molded parts Computers with recorded firmware therefore for operating system programs, and a computer interface board for controlling the operation of injection molding machines Refurbishment, maintenance, repair of injection molding machine, equipment and related components thereof, technical information and consultancy related to the maintenance of injection molding equipment, namely, injection units, molds, hot runners systems, all for injection molding systems Engineering services, technical analysis and technical research related to the design, the development and the manufacture of plastic injection molding parts; technical information, studies and consultancy related to the operation programming of injection molding equipment; custom design of molds for the manufacture of plastic products, namely, plastic parts, injection unit, molds hot runners systems, part handling devices, all for injection molding systems
48.
INSERT FOR A CLOSURE DEVICE FOR A CONTAINER AND METHOD OF MANUFACTURE THEREOF
An insert for a closure device for a container is provided, the closure device having a top panel and a skirt depending therefrom. The insert includes an outer layer made of a first material, the first material being a polymeric material that is gas permeable to allow gas through the outer layer, the outer layer including: a top surface configured to face the top panel; a bottom surface opposite the top surface; and at least one welding ridge protruding from the top surface for autogenously welding the insert to the top panel. The insert also includes an inner layer encapsulated by the outer layer, the inner layer made of a second material different from the first material, the second material having a pre-determined gas control property for controlling gas flow through the insert. A method of manufacturing an insert at a closure device is also contemplated.
B65D 51/24 - Closures not otherwise provided for combined with auxiliary devices for non-closing purposes
B29C 65/08 - Joining of preformed partsApparatus therefor by heating, with or without pressure using ultrasonic vibrations
B32B 3/08 - Layered products comprising a layer with external or internal discontinuities or unevennesses, or a layer of non-planar shapeLayered products comprising a layer having particular features of form characterised by features of form at particular places, e.g. in edge regions characterised by added members at particular parts
B65D 51/30 - Closures not otherwise provided for combined with auxiliary devices for non-closing purposes with auxiliary containers for additional articles or materials for desiccators
B65D 81/18 - Containers, packaging elements, or packages, for contents presenting particular transport or storage problems, or adapted to be used for non-packaging purposes after removal of contents providing specific environment for contents, e.g. temperature above or below ambient
B65D 81/24 - Adaptations for preventing deterioration or decay of contentsApplications to the container or packaging material of food preservatives, fungicides, pesticides or animal repellants
49.
Injection Molding of Multilayer Articles with Post-Pullback Pressure Monitoring
In one aspect, a method of molding a multilayer article comprises causing a surface layer material injection unit to commence injecting a surface layer material into a mold cavity via a surface layer material channel. Then, an internal layer material injection unit commences injecting an internal layer material into the mold cavity an internal layer material channel. Then, during application of a hold pressure upon the surface layer material in the surface layer material channel and with the surface and internal layer material injection units in fluid communication with one another, a pullback stroke is effected at the internal layer material injection unit. After a delay interval, at least one physical parameter indicative of a post-pullback pressure of the internal layer material is detected, and an indicator of pullback effectiveness is generated based on the post-pullback pressure indicated by the at least one physical parameter relative to a threshold pressure.
A plastic molding system comprises a mold assembly having external handling connectors. The mold assembly is installed to a press configured to receive the mold assembly for producing plastic articles. A robot is mounted to a frame above the press, the robot and has an end effector for lifting the mold assembly by engaging the handling connectors. The robot is movable relative to the press to install the mold assembly to the press and to remove the mold assembly from the press.
A closure (1) with a shell (2) for securement to a container neck (11) and a lid (3) pivotally connected to the shell (2) by a pair of hinge elements (6). The closure (1) also includes a pair of keys (9) depending from the lid (3) on the opposite side of the closure (1) to the hinge elements 5 (6). Each of the keys (9) is received within a keyway (90) in the shell (2), which is described in part by an overhang (93) configured to engage the key (9) when the lid (3) is pivoted relative to the shell (2) toward and/or away from a closed position.
In one aspect, a core assembly for use in a preform mold stack comprises a core insert having a base and a core sleeve. The core insert and the core sleeve define a sleeve seat and a core interface, respectively, having a complementary fit. The sleeve seat includes a substantially planar pin-contact surface having an inclination towards the base of the core insert relative to a longitudinal axis of the core insert. The core sleeve has a bore extending through a sidewall thereof at the same inclination as the substantially planar pin-contact surface. A retaining pin configured to fit within the bore has a substantially planar end surface to bear flush against the substantially planar pin-contact surface when installed to retain the core sleeve with the core insert.
B29C 45/14 - Injection moulding, i.e. forcing the required volume of moulding material through a nozzle into a closed mouldApparatus therefor incorporating preformed parts or layers, e.g. injection moulding around inserts or for coating articles
B29C 45/16 - Making multilayered or multicoloured articles
B29C 45/17 - Component parts, details or accessoriesAuxiliary operations
B29C 45/06 - Injection moulding apparatus using movable moulds on a turntable
06 - Common metals and ores; objects made of metal
07 - Machines and machine tools
42 - Scientific, technological and industrial services, research and design
Goods & Services
Injection molds of metal. Hot channels and nozzles for injection molds (parts of
machines). Design and development of plastic parts, injection molds,
casting molds and tools, hot channels and nozzles for
injection molds, electric and electronic control instruments
and apparatus.
A closure device for a container that defines a neck and an annular flange. The closure device comprises a cap body, a tamper evidence (TE) band positioned below the annular flange, a tongue that extends from the cap body towards the tamper evidence band and first and second leashes positioned on either side of the tongue. The first and second leashes connect the cap body to the tamper evidence (TE) band, and allow the cap body to be removed from the neck of the container while remaining attached to the tamper evidence (TE) band. When the cap body is actuated to a fully open position the first and second leashes act as a torsion spring for causing the tongue to exert a force against the neck of the container for retaining the cap body in the fully open position.
H-8247-0-CA ABSTRACT There is disclosed a gate assembly and related method. The gate assembly comprises a resin feedstock cutter having a cutting head, preferably a heated cutting head and most preferred comprising a heated wire, an engaging means operatively connected to the resin feedstock cutter, the engaging being configured activate the cutting head to cut residual strings of excess resin. The gate assembly being configured to attach to a shaping cell of an injection molding system. 14 Date recue/date received 2022-05-02
A closure assembly for a carton, which includes a closure, a neck to which the closure is mounted and a cutter received within the neck for piercing a foil of the carton. The closure includes a retaining ring for securement around the container neck below an annular flange of the neck, a lid pivotally connected to the retaining ring and a tamper evidence band frangibly connected to the retaining ring. The closure engages the cutter when it is rotated, which causes the cutter to pierce the foil of the carton as the closure is opened. The tamper evidence band has a rotational stop which engages a rotational stop of the container neck to separate the tamper evidence band from the retaining ring on first rotation of the closure in the opening direction.
A closure assembly for a carton, which includes a closure, a neck to which the closure is mounted and a cutter received within the neck for piercing a foil of the carton. The closure includes a retaining ring for securement around the container neck below an annular flange of the neck, a lid pivotally connected to the retaining ring and a tamper evidence band frangibly connected to the retaining ring. The closure engages the cutter when it is rotated, which causes the cutter to pierce the foil of the carton as the closure is opened. The tamper evidence band has a rotational stop which engages a rotational stop of the container neck to separate the tamper evidence band from the retaining ring on first rotation of the closure in the opening direction.
In an aspect, a mold stack may comprise two adjacent components, one at least partially defining a vent adjustable between a molding configuration and a cleaning configuration. A junction of the components may be adjustable between a molding configuration, wherein mating faces contact one another to define a parting line, and a cleaning configuration, wherein mating faces are separated to create a molding cavity extension therebetween and an auxiliary melt barrier prevents uncontrolled flashing from the extension.
A closure device for a container having a neck including an annular flange, the closure device comprising: a cap body; a tamper evident (TE) band positioned below the annular flange when assembled in the container; a first hinge and a second hinge defined on the cap body; a leash connected to the TE band, the first hinge and the second hinge; the leash allowing for the cap body to be separated from the TE band during opening, but to remain connected thereto via the leash; a tongue protruding from the cap body between the first and second hinges; when the cap body is actuated from a closed configuration relative to the neck to a fully open position: the leash is configured to retain the cap body to the TE band; an interaction of the tongue and the neck is configured to retain the cap body in the fully open position.
B65D 55/16 - Devices preventing loss of removable closure members
B65D 41/34 - Threaded or like caps or cap-like covers
B65D 47/08 - Closures with discharging devices other than pumps with pouring spouts or tubesClosures with discharging devices other than pumps with discharge nozzles or passages having articulated or hinged closures
60.
Stabilized adaptive hydraulic system pressure in an injection molding system
In one aspect, there is provided an injection molding system configured to operate in a plurality of cycles. The system comprises, amongst other things, a controller that is configured for performing a comparison of a variable pressure setpoint with a target pressure value. The controller is configured to, when the target pressure value is less than the variable pressure setpoint by at least a predetermined lower bound, (i) decrease the variable pressure setpoint to a reduced variable pressure setpoint and (ii) not further decrease the variable pressure setpoint from the reduced variable pressure setpoint until the pump assembly operates for a plurality of stabilizing cycles at the reduced variable pressure setpoint.
Disclosed herein, amongst other things, is a molded article, such as a preform that is blow moldable to form a container, and a related method of forming and recycling a container. The structure and steps includes injection molding a molded article having tubular body.
A plastic molding system comprises: dispensing, pre-shaping and shaping cells and a transport subsystem. The dispensing cell has a station for dispensing a dose of plastic feedstock. The pre-shaping and shaping cells each comprise a plurality of stations for shaping the workpiece into a preform shape and into a final shape, respectively. The transport subsystem advances a workpiece along a selected one of a plurality of process paths to form a molded article. Each of the plurality of process paths is defined by a combination of stations of the dispensing cell, the pre-shaping cell and the shaping cell.
09 - Scientific and electric apparatus and instruments
37 - Construction and mining; installation and repair services
42 - Scientific, technological and industrial services, research and design
Goods & Services
Injection molding systems consisting primarily of extruders, manifolds, molds, hot runners, controllers for controlling the injection molding system, nozzles, electric cabinets, injection screws, hoppers, heaters, pressure accumulators; hot runners for injection molding systems; melt delivery systems consisting primarily of manifolds, nozzles, heaters for injection molding; components, parts and fittings for melt delivery systems for use in injection molding machines, namely, molds, heaters, nozzles Electronic controllers for controlling the operation of melt delivery systems for use injection molding machines Refurbishing and maintenance of melt delivery systems for injection molding machines, parts and fittings thereof and controllers for melt delivery systems for injection molding provided by engineers and technicians in relation to the operation and process optimizations thereof; Technical support services, namely, troubleshooting in the nature of repair of melt delivery systems for injection molding machines, parts and fittings thereof and controllers for melt delivery systems for injection molding provided by engineers and technicians in relation to the operation and process optimizations thereof Technical support services, namely, troubleshooting in the nature of diagnosing computer hardware and software problems for melt delivery systems for injection molding machines, parts and fittings thereof and controllers for melt delivery systems for injection molding provided by engineers and technicians in relation to the operation and process optimizations thereof
A co-injection hot runner nozzle comprises an inner melt flow channel and an annular outer melt flow channel that surrounds the inner melt flow channel. The inner and outer melt flow channels have a first common source. The nozzle further comprises an annular intermediate melt flow channel disposed between the inner and outer melt flow channels. The annular intermediate melt flow channel is at least partly defined by a plurality of spiral grooves, each spiral groove having a respective inlet and defining a helical flow path. Lands between adjacent spiral grooves increase in clearance in a downstream direction. An annular axial flow path is defined over the lands. A plurality of feeder channels having a second common source is configured to supply melt to the plurality of inlets of the spiral grooves. The relationship of feeder channels to spiral grooves may be one-to-one. The inlets may be longitudinal channels.
In one aspect, a method of coinjection molding a multilayer article having a multi-segment internal layer is disclosed. A surface layer material is injected into a mold cavity from at least one of an inner outlet and an outer outlet of a multi-channel nozzle. An internal layer material is intermittently injected into the mold cavity from an intermediate outlet of the multi-channel nozzle that is between the inner and outer outlets. The intermittent injecting of the internal layer material is controlled, at least in part, by intermittent opening and closing of the intermediate outlet. An apparatus for coinjection molding the multilayer article with the segmented internal layer is also disclosed.
A method of heating plastic blanks for molding comprises, for each blank in a sequence of blanks of different types, determining a heating requirement corresponding to characteristics of the blank a molding process to be applied and heating each blank according to its heating requirement. A microwave field is generated having a defined heating rate, and the blank is placed in the microwave field for a period of time equal to the heating duration, such that the heating duration and the heating rate correspond to the heating requirement.
A method of heating plastic blanks for molding comprises, for each blank in a sequence of blanks of different types, determining a heating requirement corresponding to characteristics of the blank a molding process to be applied and heating each blank according to its heating requirement. A microwave field is generated having a defined heating rate, and the blank is placed in the microwave field for a period of time equal to the heating duration, such that the heating duration and the heating rate correspond to the heating requirement.
There is disclosed a method (400) of ejecting a molded article (310, 312) from an injection mold (100). The method (400) comprises: during a second portion of the mold opening cycle of the injection mold (100), the second portion occurring later in time relative to a first portion of the mold opening cycle of the injection mold (100): controlling velocity of at least one of: (i) the moveable mold half (102, 502) relative to the stationary mold half (104, 504), (ii) the ejector (230) relative to the moveable mold half (102, 502); and (iii) an ejector actuator linked to the core insert (112, 114, 512, 514); and (iv) a stripper actuator that is linked to the stripper sleeve (116, 516); the controlling executed such that the molded article (310, 312, 506) is ejected from the molding component with a substantially zero departure-velocity along the first axis of operation.
A molding apparatus for molding a closure device for a container. The closure device may be tethered to the container, and may open and close via a hinged articulation. The closure device includes a cylindrical body comprising hinge-connecting areas with pockets formed in the interior wall and defining an inner surface of the hinge-connecting areas, and hinges extending downwardly from the hinge-connecting areas and positioned at or below a bottom edge of the cylindrical body. The molding apparatus comprises a cavity insert component and a core component that cooperate to form mold surfaces to mold the closure device such that hinges are located below the cap area of the closure device, and hinge-connecting areas formed by projections in the core mold component and recesses in the cavity mold component are located within the cap area are flanked by membranous areas.
A molding apparatus for molding a closure device for a container. The closure device may be tethered to the container, and may open and close via a hinged articulation. The closure device includes a cylindrical body comprising hinge-connecting areas with pockets formed in the interior wall and defining an inner surface of the hinge-connecting areas, and hinges extending downwardly from the hinge-connecting areas and positioned at or below a bottom edge of the cylindrical body. The molding apparatus comprises a cavity insert component and a core component that cooperate to form mold surfaces to mold the closure device such that hinges are located below the cap area of the closure device, and hinge-connecting areas formed by projections in the core mold component and recesses in the cavity mold component are located within the cap area are flanked by membranous areas.
B65D 55/16 - Devices preventing loss of removable closure members
B29C 45/14 - Injection moulding, i.e. forcing the required volume of moulding material through a nozzle into a closed mouldApparatus therefor incorporating preformed parts or layers, e.g. injection moulding around inserts or for coating articles
B65D 41/34 - Threaded or like caps or cap-like covers
09 - Scientific and electric apparatus and instruments
37 - Construction and mining; installation and repair services
42 - Scientific, technological and industrial services, research and design
Goods & Services
(1) Injection molding machines and parts and fittings therefor; Replacement parts for injection molding machinery, and accessories thereof, product handling equipment namely, conveyors, stackers, sorters, packers, cranes, automated lifting and clamping devices to lift and clamp injection molded parts.
(2) Computers with firmware and a human machine interface for controlling the operation of injection molding machines. (1) Refurbishment, maintenance, repair of injection molding machine, equipment and related components thereof, namely steel molds used to produce plastic parts, product handling equipment namely, conveyors, stackers, sorters, packers, cranes, automated lifting and clamping devices to lift and clamp injection molded parts, computers with firmware and a human machine interface for controlling the operation of injection molding machines, robots for removing molded plastic parts from an industrial steel mold.
(2) Providing engineering and technical support on the operation and maintenance of injection molding machinery, equipment and related components thereof, namely steel molds used to produce plastic parts, product handling equipment namely, conveyors, stackers, sorters, packers, cranes, automated lifting and clamping devices to lift and clamp injection molded parts, computers with firmware and a human machine interface for controlling the operation of injection molding machines, robots for removing molded plastic parts from an industrial steel mold.
A closure (1) with a shell (2) for securement to a container neck (11) and a lid (3) pivotally connected to the shell (2) by a pair of hinge elements (6). The closure (1) also includes a pair of bridges on opposite sides of the closure (1). Each of the bridges is in the form of a C-shaped loop that projects radially outwardly from each of the shell (2) and the lid (3) such that it straightens, in use, before breaking when the lid (3) is pivoted relative to the shell (2) toward an open position.
B65D 43/16 - Non-removable lids or covers hinged for upward or downward movement
B29C 45/17 - Component parts, details or accessoriesAuxiliary operations
B65D 50/00 - Closures with means for discouraging unauthorised opening or removal thereof, with or without indicating means, e.g. child-proof closures
B65D 50/06 - Closures with means for discouraging unauthorised opening or removal thereof, with or without indicating means, e.g. child-proof closures openable or removable by the combination of plural actions requiring the combination of different actions in succession
A closure (1, 101) with a shell (2, 102) for securement to a container neck (11) and a lid (3, 103) pivotally connected to the shell (2, 102) by a pair of hinge elements (6, 106). The closure (1, 101) also includes a pair of bridges (9, 109) each frangibly connecting the side wall (5, 105) of the lid (3, 103) to an outer side of a respective one of the hinge elements (6, 106) or to a tab (126) projecting from the shell (2, 102) into the void between the side wall (5, 105) and one of the hinge elements (6, 106). The bridges (9,109) are configured to break when the lid (3, 103) is pivoted relative to the shell (2, 102) toward an open position.
B65D 47/08 - Closures with discharging devices other than pumps with pouring spouts or tubesClosures with discharging devices other than pumps with discharge nozzles or passages having articulated or hinged closures
06 - Common metals and ores; objects made of metal
07 - Machines and machine tools
42 - Scientific, technological and industrial services, research and design
Goods & Services
(1) Injection molds of metal.
(2) Hot channels and nozzles for injection molds (parts of machines). (1) Design and development of plastic parts, injection molds, casting molds and tools, hot channels and nozzles for injection molds, electric and electronic control instruments and apparatus.
09 - Scientific and electric apparatus and instruments
37 - Construction and mining; installation and repair services
42 - Scientific, technological and industrial services, research and design
Goods & Services
(1) Injection molding systems; hot runners for injection molding systems; melt delivery systems for injection molding; components, parts and fittings for melt delivery systems for use in injection molding machines; controllers for controlling the operation of melt delivery systems for use in injection molding machines (1) Refurbishment, maintenance and support services provided by engineers and technicians in relation to the operation and process optimizations of melt delivery systems for injection molding machines, parts and fittings thereof and controllers for melt delivery systems for injection molding
81.
MACHINE AND METHOD FOR INJECTION MOLDING MULTILAYER ARTICLES HAVING A HIGH PROPORTION OF INTERNAL LAYER MATERIAL
In one aspect, a method of coinjection molding a multilayer article using a coinjection nozzle having inner outlet, an outer outlet, and an intermediate outlet between the inner and outer outlets is provided. A stream of surface layer material is injected into a mold cavity from the intermediate outlet. With the injection ongoing, two streams of internal layer material are injected from the inner and outer outlets of the coinjection nozzle respectively. The two streams sandwich the stream of surface layer material and flow behind a melt front of the surface layer material. The sandwiched stream of surface layer material continues to supply the melt front with surface layer material at least until the melt front nears a distal end of the mold cavity. The resultant article is substantially or entirely encapsulated by a skin of the surface layer material and contains a high proportion of internal layer material.
B29C 45/14 - Injection moulding, i.e. forcing the required volume of moulding material through a nozzle into a closed mouldApparatus therefor incorporating preformed parts or layers, e.g. injection moulding around inserts or for coating articles
B29C 45/16 - Making multilayered or multicoloured articles
In one aspect, a method of coinjection molding a multilayer article using a coinjection nozzle having inner outlet, an outer outlet, and an intermediate outlet between the inner and outer outlets is provided. A stream of surface layer material is injected into a mold cavity from the intermediate outlet. With the injection ongoing, two streams of internal layer material are injected from the inner and outer outlets of the coinjection nozzle respectively. The two streams sandwich the stream of surface layer material and flow behind a melt front of the surface layer material. The sandwiched stream of surface layer material continues to supply the melt front with surface layer material at least until the melt front nears a distal end of the mold cavity. The resultant article is substantially or entirely encapsulated by a skin of the surface layer material and contains a high proportion of internal layer material.
B29C 45/16 - Making multilayered or multicoloured articles
B29C 45/14 - Injection moulding, i.e. forcing the required volume of moulding material through a nozzle into a closed mouldApparatus therefor incorporating preformed parts or layers, e.g. injection moulding around inserts or for coating articles
In one aspect, an injection unit for an injection molding machine having a hot runner with a sprue comprises a heated melt pipe configured to convey a continuous stream of melt, a shooting pot assembly, and a telescopic melt coupling. The shooting pot assembly is configured to convert the continuous stream of melt from the heated melt pipe into batches for cyclical injection and is translatable between a sprue-engagement position and a sprue-disengagement position. The telescopic melt coupling is configured to convey melt from the heated melt pipe to the shooting pot assembly and has a variable length. The variable length telescopic melt coupling permits translation of the shooting pot assembly, relative to the heated melt pipe, between the sprue-engagement position and the sprue-disengagement position while maintaining a fluid melt interconnection between the heated melt pipe and the shooting pot assembly.
In one aspect, an injection unit for an injection molding machine having a hot runner with a sprue comprises a heated melt pipe configured to convey a continuous stream of melt, a shooting pot assembly, and a telescopic melt coupling. The shooting pot assembly is configured to convert the continuous stream of melt from the heated melt pipe into batches for cyclical injection and is translatable between a sprue-engagement position and a sprue-disengagement position. The telescopic melt coupling is configured to convey melt from the heated melt pipe to the shooting pot assembly and has a variable length. The variable length telescopic melt coupling permits translation of the shooting pot assembly, relative to the heated melt pipe, between the sprue-engagement position and the sprue-disengagement position while maintaining a fluid melt interconnection between the heated melt pipe and the shooting pot assembly.
An injection mold (100) including a core plate assembly (200), a cavity plate assembly (400) and a stripper plate assembly (300) arranged between the core and cavity plate assemblies (200, 400). The mold (100) includes a plurality of mold stacks (MS) with a molding configuration, in which the mold stacks (MS) are closed to define molding cavities. A gap (G) is provided between the core plate (210) and the stripper plate (310) when the mold (100) is in the molding configuration, such that a clamping load (CL) applied to urge the core plate (210) toward the cavity plate (410) is directed substantially entirely through the mold stacks (MS).
A closure device for a container having a neck including an annular flange, the closure device comprising: a cap body; a tamper evident (TE) band positioned below the annular flange when assembled in the container; a first hinge and a second hinge defined on the cap body; a leash connected to the TE band, the first hinge and the second hinge; the leash allowing for the cap body to be separated from the TE band during opening, but to remain connected thereto via the leash; a tongue protruding from the cap body between the first and second hinges; when the cap body is actuated from a closed configuration relative to the neck to a fully open position: the leash is configured to retain the cap body to the TE band; an interaction of the tongue and the neck is configured to retain the cap body in the fully open position.
40 - Treatment of materials; recycling, air and water treatment,
37 - Construction and mining; installation and repair services
41 - Education, entertainment, sporting and cultural services
42 - Scientific, technological and industrial services, research and design
Goods & Services
Leasing of injection molding machines and accessories thereof; Consultation in the field of the manufacture of plastic injection molding parts Installation, maintenance, diagnosis and repair of injection molding systems, injection molding machines and parts and fittings thereof, injection molding equipment, and controllers for injection molding machines; refurbishment of injection molding machines, equipment and related components; Technical support, namely, technical advice concerning the maintenance of plastic injection molding equipment; Planning and laying out of factory buildings Technical support, namely, training in the operation of plastic injection molding equipment Engineering services, namely, consultancy services related to the design and development of plastic injection molding parts; custom design of molds for plastic products; structural and functional analysis of injection molding systems, injection molding machines, equipment, controllers, and robotics using system operating reports generated from real-time data collected; design of plastic injection molding parts to customer specifications
09 - Scientific and electric apparatus and instruments
11 - Environmental control apparatus
Goods & Services
Injection molding machines for molding plastics and other synthetic resins; related accessories for injection molding machines for molding plastics and other synthetic resins, namely, robots for removing molded parts, product handling equipment, namely, conveyor lines, stacking machines, sorting machines for sorting molded parts, packing machines, cranes, machines tools, namely, clamps for use in the precision clamping of work pieces, pumps for cooling engines for injection molding machines, controls, take-off units for removing molded plastic parts from the mold of the injection molding machine, and scrap grinders being power tools; molds for injection molding machines for molding plastics and other synthetic resins Industrial automation controls for injection molding machines Cooling units for industrial purposes for injection molding machines; Heating systems composed primarily of tubes, pipes, and manifolds through which warm or high temperature water circulates for injection molding machines
a) face abuts the front face (CVF) of the cavity plate (410). Each cavity insert (440) also includes a molding surface (448) along its length, at least two thirds of which extends beyond the cavity plate (410).
There is provided a structure for positioning a first mold part of a mold on a mold mounting face in an injection molding machine. The structure comprises a positioner configured to connect the first mold part to part of the injection molding machine, wherein the positioner is adjustable to position the first mold part on the mold mounting face. The structure further comprises controller executable instructions executable in a controller with which to resolve an alignment parameter of the mold using a feedback signal from a sensor. Further provided is a method of operating an injection molding machine which method comprises the steps of positioning a first mold part of a mold on a mold mounting face using a positioner and appreciating an alignment parameter of the mold with reference to a feedback signal from a sensor.
In one aspect there is disclosed a method of improving shot repeatability in a multilayer reciprocating screw injection molding apparatus by preventing pressure communication or "cross-talk" between melt channels. In the first aspect an outlet nozzle valve is closed prior to closing a check valve within an injection unit of the multilayer reciprocating screw injection molding apparatus. In another aspect there is disclosed a method of improving shot repeatability in a reciprocating screw injection molding apparatus by recording a first position of a screw within the barrel of an injection unit of a reciprocating screw injection molding apparatus, the first position corresponding to a volume of melt within the barrel of the material injection unit. A second position of the screw is then calculated based on the first position, the second position corresponding to a transition position of the screw within the barrel of the injection unit of the reciprocating screw injection molding apparatus.
In one aspect there is disclosed a method of improving shot repeatability in a multilayer reciprocating screw injection molding apparatus by preventing pressure communication or "cross-talk" between melt channels. In the first aspect an outlet nozzle valve is closed prior to closing a check valve within an injection unit of the multilayer reciprocating screw injection molding apparatus. In another aspect there is disclosed a method of improving shot repeatability in a reciprocating screw injection molding apparatus by recording a first position of a screw within the barrel of an injection unit of a reciprocating screw injection molding apparatus, the first position corresponding to a volume of melt within the barrel of the material injection unit. A second position of the screw is then calculated based on the first position, the second position corresponding to a transition position of the screw within the barrel of the injection unit of the reciprocating screw injection molding apparatus.
A preform mold (100) including a core plate (210), a cavity plate (410) and a plurality of mold stacks (MS) mounted between the core and cavity plates (210, 410). Each mold stack (MS) includes a core insert (250) mounted to the core plate (210), a cavity insert (440) mounted to the cavity plate (410) and split mold inserts (350) mounted between the core and cavity inserts (250, 440). The core inserts (250) are mounted to the core plate (210) by fasteners accessible from a rear side of the core plate (210). When the mold (100) is assembled, the core inserts (250) can be secured by the fasteners in a fixed condition in which they are immovable relative to the core plate (210). Also disclosed is a method of aligning the core inserts (250) by securing the core inserts (250) from a floating condition, in which they are able to slide relative to the core plate (210) along a sliding interface therebetween, to the fixed condition.
There is provided a system, a method and preform suitable for executing liquid forming of the preform into a final-shaped container. The present technology includes various improvements to methods, apparatuses, and systems for forming final-shaped containers from preforms using a liquid destined to be contained in the final-shaped container.
37 - Construction and mining; installation and repair services
40 - Treatment of materials; recycling, air and water treatment,
42 - Scientific, technological and industrial services, research and design
Goods & Services
Installation, maintenance, diagnosis and repair of injection
molding systems, injection molding machines and parts and
fittings thereof, injection molding equipment, and
controllers for injection molding machines; refurbishment of
injection molding machines, equipment and related
components. Leasing of injection molding machines and accessories
thereof. Engineering services, namely consultancy services related to
the design, the development and the manufacture of plastic
injection molding parts, technical support on the operation
and maintenance of plastic injection molding equipment,
custom designing molds for plastic products, factory
planning services, analysis of system operating reports
generated from real-time data collected from injection
molding systems, injection molding machines, equipment,
controllers, robotics, and the design of plastic injection
molding parts to customer specifications.
An injection molding apparatus comprises a support base and a mold carrier removably mounted to the support base. The mold carrier includes a mounting plate with attachment features for engaging the support base. A mold with two mold plates is slidably mounted to the mounting 5 plate. A clamp is operable to move the plates between open and closed positions. In the closed position, the plates abut one another. In the open position, the plates are spaced apart for removing molded articles.
A plastic molding method comprises moving each part of a plurality of parts along a selected one of a plurality of possible paths through dispensing and molding stations of a molding system. A controller tracks an operating state of each station, selects process stations capable of receiving a part for processing; identifies parts capable of processing at the selected process stations, and assigns individual parts to individual process stations.
A plastic molding method comprises moving each part of a plurality of parts along a selected one of a plurality of possible paths through dispensing and molding stations of a molding system. A controller tracks an operating state of each station, selects process stations capable of receiving a part for processing; identifies parts capable of processing at the selected process stations, and assigns individual parts to individual process stations.
