Claims
- 1. A co-injection nozzle having a central injection channel with an open end and providing an injection path for injecting streams of melt materials to form a multi-layer article from said melt material streams,
- said nozzle comprising interfitting axially concentric members, including at least an interfitting shell and an outer nozzle cap, each member having inner and outer surfaces, the inner surface of the nozzle cap having a frustoconical portion enclosing at least a portion of the outer surface of said interfitting shell, an enclosed portion of the outer surface of the shell having a frustoconical shape,
- said outer and inner frustoconical surface portions being adapted and cooperating to form an annular melt material flow passageway having a fixed tapered frustoconical portion of substantially invariable dimension which terminates at a fixed, annular orifice whose dimension is substantially invariable for flow of a melt material therethrough, for injection of the material from the nozzle.
- 2. The co-injection nozzle of claim 1 wherein at least the nozzle cap has a feed channel for flow of melt material therethrough, and which leads to the flow passageway having the fixed tapered portion.
- 3. The co-injection nozzle of claim 1 wherein a portion of said tapered frustoconical passageway portion near said orifice is symmetrical.
- 4. The co-injection nozzle of claim 1 wherein said orifice is located from about 100 to about 900 mils from the open end of the nozzle.
- 5. The co-injection nozzle of claim 4 wherein said orifice is located from about 100 to about 300 mils from the open end of the nozzle.
- 6. The co-injection nozzle of claim 1 wherein said interfitting shell comprises a first interfitting shell and said interfitting axially concentric members further comprises a second interfitting shell at least partially enclosed by said first interfitting shell, a third interfitting shell at least partially enclosed by said second interfitting shell, and a fourth interfitting shell at least partially enclosed by said third interfitting shell.
- 7. A co-injection nozzle providing an axial central injection path through an open end of the nozzle, for injecting streams of melt materials to form a multi-layer article from said melt material streams, said article comprising an outside layer, an inside layer, and an internal oxygen barrier layer between said outside layer and said inside layer, said nozzle comprising
- a flow passageway for each stream of melt material, at least two of said passageways being fixed and terminating at an associated fixed orifice, at least the orifice for the material stream which forms the internal oxygen barrier layer being of substantially invariable dimension, said orifices being positioned to direct the melt materials into said injection path from locations close to the open end of the nozzle,
- at least the passageway for flow of the material stream which forms the internal oxygen barrier layer being adapted to provide a balanced flow of material through and around said passageway, including a symmetrical, fixed, tapered portion of substantially invariable dimension for the melt material for said internal layer in said passageway adjacent the orifice terminating the passageway for melt material for said internal layer for balanced flow of said material through said orifice into said injection path.
- 8. The nozzle of claim 7 wherein the orifice for the melt material for the internal oxygen barrier layer is within about 100 to about 900 mils from the open end of the nozzle.
- 9. The injection nozzle of claim 8 further comprising means in the nozzle and moveable through the nozzle to prevent or permit flow of the melt material for the internal layer into the injection path and to clear material from the injection path.
- 10. The nozzle of claim 7 wherein the orifice terminating the passageway for the melt material for the eternal oxygen barrier layer is within about 100 to about 650 mils from the open end of the nozzle.
- 11. The injection nozzle of claim 10 further comprising means in the nozzle and moveable through the nozzle to prevent or permit flow of the melt material for the internal layer into the injection path and to clear material from the injection path.
- 12. The nozzle of the claim 7 wherein the orifice terminating the passageway for the melt material for the internal oxygen barrier layer is within about 100 to about 300 mils of the open end of the nozzle.
- 13. The injection nozzle of claim 12 further comprising means in the nozzle and moveable through the nozzle to prevent or permit flow of the melt material for the internal layer into the injection path and to clear material from the injection path.
- 14. The injection nozzle of claim 7 further comprising means in the nozzle and moveable through the nozzle to prevent or permit flow of the melt material for the internal layer into the injection path and to clear material from the injection path.
- 15. The injection nozzle of claim 7 wherein the symmetrical, fixed, tapered portion of the passageway for flow of the material stream which forms the material oxygen barrier layer is frustoconically tapered.
- 16. The co-injection nozzle of claim 15 wherein each passageway has an associated orifice, and the orifices are located as close as possible to each other and as close as possible to the open end of the co-injection nozzle.
- 17. The co-injection nozzle of claim 7 wherein there are a plurality of such nozzles in an injection molding apparatus for forming a plurality of multi-layer containers, and the apparatus comprises
- a source of polymer material located upstream of the nozzles, for each material which is to form a layer of the plurality of multi-layer containers,
- means for moving each polymer material which is to form a layer of the plurality of multi-layer containers to each nozzle,
- a flow channel for channelling each polymer material to each co-injection nozzle, each nozzle being in communication with a flow channel and said means for moving for each material which is to form a layer of the container,
- each flow channel for a given material being separate and having a portion extending from an associated one of the plurality of nozzles with which it communicates to the means for moving for the given material, and providing substantially the same flow experience for the given material in its path to the associated nozzle as is provided for the given material in its path to the other nozzles.
- 18. The co-injection nozzle apparatus of claim 17 wherein runner means channels the polymer melt materials separately radially towards the nozzle means and alone or cooperatively with the nozzle means changes the direction of flow of the materials and feeds each melt material separately axially into a rear portion of the co-injection nozzle assemblies and to that material's flow passageway.
- 19. The co-injection nozzle apparatus of claim 17 wherein the machine has a long runner system feeding each polymer material to each of the injection nozzle assemblies.
- 20. The co-injection nozzle apparatus of claim 19 wherein the fixed orifice terminating the passageway for the melt material for forming the internal layer is located within from about 100 to about 900 mils of the open end.
- 21. The co-injection nozzle apparatus of claim 19 wherein the fixed orifice terminating the passageway for the melt material for forming the internal layer is located within from about 100 to about 650 mils of the open end.
- 22. The co-injection nozzle apparatus of claim 19 wherein the fixed orifice terminating the passageway for the melt material for forming the internal layer is located within from about 100 to about 300 mils of the open end.
- 23. The co-injection nozzle apparatus of claim 17 wherein the fixed orifice terminating the passageway for the melt material for forming the internal layer is located within from about 100 to about 900 mils of the open end.
- 24. The co-injection nozzle apparatus of claim 23 further comprising valve means in the nozzle selectively moveable to prevent or permit flow of the melt material which forms said internal layer.
- 25. The co-injection nozzle apparatus of claim 23 wherein each passageway for each material has an orifice and each orifice is located as close as possible to each other and as close as possible to the open end of the nozzle.
- 26. The co-injection nozzle apparatus for claim 17 wherein the fixed orifice terminating the passageway for the melt material for forming the internal layer is located within from about 100 to about 650 mils of the open end.
- 27. The co-injection nozzle apparatus of claim 17 wherein the fixed orifice terminating the passageway for the melt material for forming the internal layer is located within from about 100 to about 300 mils of the open end.
- 28. The co-injection nozzle apparatus of claim 17 wherein each passageway for each material has an orifice and each orifice is located as close as possible to each other and as close as possible to the open end of the nozzle.
- 29. The co-injection apparatus of claim 17, wherein the means for defining a flow channel comprises a means for defining a distinct flow channel associated with each flow passageway for directing melt material into the nozzle.
- 30. The co-injection nozzle of claim 7, wherein said multi-layer article further comprises,
- an outside intermediate layer between said outside layer and said internal oxygen barrier layer, and
- an inside intermediate layer between said inside layer and said internal oxygen barrier layer,
- wherein a separate stream of melt material is injected for each layer of said multi-layered article.
- 31. The co-injection nozzle of claim 7, wherein said nozzle comprises at least three flow passageways.
- 32. The co-injection nozzle of claim 31, wherein said nozzle comprises five flow passageways.
- 33. The co-injection nozzle of claim 7, wherein each flow passageway has a distinct flow channel associated therewith for directing melt material into the co-injection nozzle.
- 34. A co-injection nozzle having a central channel with an open end and providing a central injection path therethrough for injecting streams of melt material into an injection cavity mold to form a multi-layer article from said streams, said article comprising an outside layer, an inside layer, and an internal oxygen barrier layer between said outside layer and said inside layer, said nozzle comprising
- a flow passageway for each stream of melt material, at least two of said passageways being fixed and annular and each terminating at an associated fixed annular orifice of substantially invariable dimension communicating with said injection path from locations close to the open end,
- at least the passageway for flow of the material stream which forms the internal oxygen barrier layer being adapted to provide a balanced flow of material through and around said passageway, including a fixed, symmetrical tapered passageway portion of substantially invariable dimension for the melt material for said internal layer in said passageway adjacent said associated orifice for balancing flow of said material through said orifice into said injection path.
- 35. The nozzle of claim 34 wherein the orifice terminating the passageway for the internal oxygen barrier layer is within from about 100 to about 900 mils of the open end.
- 36. The nozzle of claim 35 further comprising valve means in the nozzle selectively moveable to prevent or permit flow of the melt material which forms said internal layer into said central injection path.
- 37. The nozzle of claim 34 wherein the orifice terminating the passageway for the internal oxygen barrier layer is within from about 100 to about 650 mils of the open end.
- 38. The nozzle of claim 37 further comprising valve means in the nozzle selectively moveable for preventing or permitting flow of the melt material which forms said internal layer into said central injection path.
- 39. The nozzle of claim 34 wherein the orifice terminating the passageway for the internal oxygen barrier layer is within from about 100 to about 300 mils of the open end.
- 40. The nozzle of claim 39 further comprising valve means in the nozzle selectively moveable to prevent or permit flow of the melt material which forms said internal layer into said central injection path.
- 41. The nozzle of claims 34 further comprising valve means in the nozzle selectively moveable to prevent or permit flow of the melt material which forms said internal layer into said central injection path.
- 42. A multi-co-injection nozzle injection molding apparatus for an injection molding machine, for injection molding a plurality of multi-layer, multi-material plastic articles, which comprises,
- a source of polymer material for each material which is to form a layer of the plurality of articles,
- runner means communicating with and located downstream of each source of polymer material,
- a plurality of co-injection nozzles, each nozzle providing an axial central injection path, and a plurality of polymer flow stream fixed passageways each with an orifice in communication with the injection path and each mounted in front of the runner means, the runner means including a plurality of polymer flow stream channels each for separately channelling a polymer melt material which is to form a layer of the plurality of articles from the source of the polymer material to each of more than one of the co-injection nozzles, each nozzle having an associated passageway for receiving each material which is to form a layer, and
- means for moving each polymer material through each flow channel and into its associated nozzle.
- 43. The apparatus of claim 42 wherein each co-injected nozzle comprises a valve cooperatively associated with and operative within and through the central injection path for independently controlling the time of initiation and termination of each of the respective polymer melt materials for controlling the injection of said respective materials from each of the more than one of the co-injection nozzles into an associated juxtaposed injection cavity.
- 44. The apparatus of claim 44 wherein there is included valve means associated with the runner means for cooperatively controlling the flow and non-flow of each of the respective polymer melt materials to the nozzles and from their orifices into the injection path of the injection nozzles for controlling the injection of said respective materials from each of the more than one of the co-injection nozzles into an associated juxtaposed injection cavity.
- 45. The apparatus of claim 42 wherein each co-injection nozzle comprises a valve for independently controlling the time of initiation and termination of each of the respective polymer melt materials into the injection path for controlling the injection of said respective materials from each of the more than one of the co-injection nozzles into an associated juxtaposed injection cavity, and control means for actuating the valve simultaneously in each co-injection nozzle means.
- 46. The apparatus of claim 45 wherein each co-injection nozzle includes a gate and an axial central channel extending through the gate, and wherein there is included means for uniformly distributing the flow of individual polymer materials within the co-injection nozzle central channel feeding the nozzle's associated juxtaposed injection cavity.
- 47. The apparatus of claim 42 wherein the moving means comprises means for pressurizing one or more polymer materials including that which is to form an internal layer of the article in said internal layer material's co-injection nozzle passageway prior to injection of said material into a cavity,
- each flow channel for each material which is to form a layer of the article is split into separate branched flow channels there being a separate branched flow channel for each material fed to each nozzle,
- a plurality of valve means operatively associated with the co-injection nozzles, said plurality of valve means including separate valve means for each co-injection nozzle and operable through each co-injection nozzle's central injection path to allow or prevent injection of the respective polymeric materials from the nozzle into its mold cavity,
- drive means for driving each of said separate valve means substantially identically through the injection path of each of the co-injection nozzles to provide substantially identical control over the initiation and termination of the flows of the polymer materials from each of the co-injection nozzles, and
- control means connected to the drive means for moving the valve means in a desired mode which provides said substantially identical movements of said separate valve means in said respective co-injection nozzles.
- 48. The apparatus of claim 47 wherein the internal layer has a leading edge in a side wall of the container, and the control means include means in communication with the moving means and operative such that the moving means can substantially simultaneously pressurize the internal layer material in its passageway in each respective co-injection nozzle prior to injection of the material into the nozzle's mold cavity, so that the internal layer leading edge is substantially unbiased relative to the terminal end of the side wall.
- 49. The apparatus of claim 47 wherein the control means includes means to effect substantially simultaneous control of the flow or non-flow of corresponding material streams in the respective co-injection nozzles.
- 50. The apparatus of claim 49 wherein the control means includes a microprocessor and a program to effect said substantially identical movements and substantially simultaneous pressurization and control.
- 51. The apparatus of claim 47 wherein the valve means is operative to prevent flow of the internal layer material into the cavity and the control means is adapted to raise the pressure of the arrested internal layer material to a level above the pressure of the materials which are to form other layers of the articles.
- 52. The apparatus of claim 51 wherein the co-injection nozzle flow stream passageway for the internal layer material is fixed and has a fixed annular orifice, and the valve means is operative substantially simultaneously for each of the nozzles to establish substantially simultaneous onset of flow of the internal layer material from its annular fixed orifices into the central injection paths of the nozzles.
- 53. The apparatus of claim 42, wherein said associated passageway of said nozzle for receiving each material which is to form a layer of said articles comprises a distinct passageway for each of said plurality of polymer flow stream fixed passageways of said nozzle.
- 54. The apparatus of claim 53, wherein said plurality of polymer flow stream fixed passageways of each nozzle comprises five polymer flow stream fixed passageways.
- 55. A multi-coinjection nozzle injection molding apparatus for an injection molding machine for injection molding a plurality of five layer rigid plastic parisons for blow molding into containers, the parisons having an outside surface layer, an inside surface layer, and internal layers including a relatively central layer and intermediate layers, one intermediate layer to each side of the central layer between it and the respective inside and outside surface layers, which comprises,
- a source of polymer material for each material which is to form a layer of the plurality of parisons there being a source of material for forming the outside and inside surface layers, a source of material for forming the intermediate layers and a source of material for forming the central layer,
- a plurality of coinjection nozzles each having an open end, a gate at the open end, a central channel comprising the gate and defining an injection path, and a plurality of polymer flow stream fixed passageways each having a fixed orifice substantially in communication with the injection path, each nozzle including interfitting members fixed relative to one another and providing said fixed passageways and orifices,
- a runner system including a plurality of polymer flow channels, there being a flow channel for separately channelling each polymer melt material which is to form a layer of the plurality of parisons from the material's source to the plurality of co-injection nozzles,
- means for moving each polymer material which is to form a layer of the parisons separately from its source through the runner system to each co-injection nozzle, the moving means comprising
- a first common moving means associated with a said flow channel for the material which is injected through a nozzle to form the outside and inside surface layers for moving the material through the flow channel and nozzle to form the outside and inside surface layers,
- a second common moving means associated with a said flow channel for the material which is injected through a nozzle to form the intermediate layers for moving the material through the flow channel and nozzle to form the intermediate layers, and
- separate valve means associated with each nozzle to prevent and allow flow of the respective polymer materials at different times from the nozzles.
- 56. The apparatus of claim 55 wherein the separate valve means operate in and through the injection path of each nozzle to prevent and allow flow of the respective materials from their orifices into the injection path.
- 57. The apparatus of claim 56 wherein the flow channels are adapted to provide essentially the same polymer flow experience for the intermediate layer material in its path from the second common moving means to the plurality of nozzles.
- 58. The apparatus of claim 56 wherein the nozzles are adapted to provide substantially the same polymer flow for the intermediate layer material in each nozzle.
- 59. The apparatus of claim 56 wherein the runner system is adapted to minimize the differences in flow history of the material for forming the intermediate layer in its path to each nozzle.
- 60. The apparatus of claim 55 wherein the flow channels are adapted to provide essentially the same polymer flow experience for the intermediate layer material in its path from the second common moving means to the plurality of nozzles.
- 61. The apparatus of claim 55 wherein the nozzles are adapted to provide substantially the same polymer flow for the intermediate layer material in each nozzle.
- 62. The apparatus of claim 55 wherein the runner system is adapted to minimize the differences in flow history of the material forming the intermediate layer in its path to each nozzle.
- 63. The apparatus of claim 62 wherein the nozzles are adapted to provide substantially identical flow of the intermediate layer material in the nozzles.
- 64. The apparatus of claim 55 wherein there is included valve means associated with the runner means for cooperatively controlling the flow and non-flow of each of the respective polymer melt materials to the nozzles and from their orifices into the injection path of the injection nozzles for controlling the injection of said respective materials from each of the more than one of the co-injection nozzles into an associated juxtaposed injection cavity.
- 65. The apparatus of claim 55, wherein each polymer flow stream fixed passageway of each co-injection nozzle has a distinct polymer flow channel associated therewith for directing polymer melt material into the associated co-injection nozzle.
- 66. A multi-coinjection nozzle injection molding apparatus, which comprises a plurality of co-injection nozzles each for injecting one or more polymer materials into an associated one of a plurality of injection cavity molds to form a plurality of multi-polymer at least three-layer containers each nozzle being comprised of interfitting members and being adapted to inject the respective materials through a forward end,
- a source of polymer material for each material which is to form a layer of the containers,
- runner means for providing a flow channel which is split into branched flow channels for each material which is to form a layer of the containers, and
- moving means for moving each material through its flow channel and branched channels, there being a branched channel for each material leading separately to each nozzle, so that each nozzle is in communication with a set of branched flow channels, each set including at least a separate branched channel for each material which is to form a layer of the container, each material being directed through its branched channel along a path a downstream portion of which directs the material radially toward the axis of a rearward portion of each nozzle, where the material is then directed to and along a path parallel to the axis of the nozzle, such that each material communicates with and passes into a rearward portion of the nozzle and travels axially through the nozzle for injection through the forward end of the nozzle.
- 67. The apparatus of claim 66, wherein the at least three layer container comprises a five layer container.
- 68. The apparatus of claim 67, wherein the at least a separate branched channel comprises a distinct branched channel for each layer of the container.
- 69. A co-injection nozzle having a central injection channel with an open end and providing an injection path for injecting streams of melt materials to form a multi-layer article from said melt material streams,
- said nozzle comprising interfitting axially concentric members, including at least an interfitting shell and an outer nozzle cap, each member having inner and outer surfaces, the nozzle cap enclosing at least a portion of said interfitting shell;
- said nozzle cap and interfitting shell cooperating to form a melt material flow passageway having a fixed tapered portion of substantially invariable dimension which terminates at a fixed orifice having substantially invariable dimension for flow of a melt material therethrough, for injection of the material from the nozzle.
- 70. The co-injection nozzle of claim 69 wherein said interfitting shell comprises a first interfitting shell and said interfitting axially concentric members further comprises a second interfitting shell at least partially enclosed by said first interfitting shell, a third interfitting shell at least partially enclosed by said second interfitting shell, and a fourth interfitting shell at least partially enclosed by said third interfitting shell.
- 71. A co-injection nozzle providing an axial central injection path through an open end of the nozzle, for injecting streams of melt materials to form a multi-layer article from said melt material streams, said nozzle comprising
- a first flow passageway;
- a second flow passageway adjacent to said first flow passageway; and
- a third flow passageway adjacent to said second flow passageway;
- at least two of said first, second and third flow passageways being fixed and terminating at an associated fixed orifice;
- at least the orifice for the second flow passageway being of substantially invariable dimension, said orifices being positioned to direct the melt materials into said injection path from locations close to the open end of the nozzle; and
- at least the second flow passageway being adapted to provide a balanced flow of material through and around said passageway, including a symmetrical, fixed, tapered portion of substantially invariable dimension adjacent the orifice terminating the second flow passageway for balanced flow of said material through said orifice into said injection path.
- 72. The co-injection nozzle of claim 71, wherein the at least three flow passageways comprises five flow passageways.
- 73. The co-injection nozzle of claim 71, wherein each of said flow passageways and associated fixed orifices are annular.
- 74. The co-injection nozzle of claim 71 wherein each of the at least three flow passageways has a distinct flow channel associated therewith for directing melt material into the co-injection nozzle.
Parent Case Info
This application is a continuation of Ser. No. 08/341,700, filed Nov. 18, 1994, now U.S. Pat. No. 5,523,045, which is a continuation of Ser. No. 07/740,749 filed Aug. 5, 1991, now abandoned, which is a continuation of Ser. No. 07/563,169, filed Aug. 3,1990, now U.S. Pat. No. 5,037,285, which is a continuation of Ser. No. 07/397,348, filed Aug. 22, 1989, now U.S. Pat. No. 4,946,365, which is a continuation of Ser. No. 07/283,000, filed Dec. 2, 1988, now abandoned, which is a continuation of Ser. No. 06/909,941, filed Sep. 19, 1986, now abandoned, which is division of Ser. No. 06/484,707, filed Apr. 13, 1983, now U.S. Pat. No. 4,712,990.
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