최소 단어 이상 선택하여야 합니다.
최대 10 단어까지만 선택 가능합니다.
다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
NTIS 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
DataON 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
Edison 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
Kafe 바로가기국가/구분 | United States(US) Patent 등록 |
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국제특허분류(IPC7판) |
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출원번호 | UP-0434806 (2006-05-17) |
등록번호 | US-7780895 (2010-09-13) |
발명자 / 주소 |
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 | 피인용 횟수 : 4 인용 특허 : 7 |
Methods and apparatus adjustably control the repositioning of non-homogeneous fluid conditions across the stream of a laminar flowing fluid to a desirable circumferential position. The invention is particularly applicable to controlling non-homogeneous melt conditions in hot or cold runner systems.
Methods and apparatus adjustably control the repositioning of non-homogeneous fluid conditions across the stream of a laminar flowing fluid to a desirable circumferential position. The invention is particularly applicable to controlling non-homogeneous melt conditions in hot or cold runner systems. Various mechanisms are provided that enable simple adjustments of a flow diverter within a fluid rotation device, making either static or dynamic adjustments, so that the degree of fluid flow repositioning in a runner system can be changed without the need for mold disassembly or retooling. Various forms of actuators effect adjustment and may be manually manipulated or manipulated through various powered devices.
What is claimed is: 1. A method of adjustably controlling the position of non-homogeneous conditions that occur across a stream of laminar flowing material that flows at a first level in at least one flow path of a tool, comprising: providing within at least one flow path of the tool an adjustable
What is claimed is: 1. A method of adjustably controlling the position of non-homogeneous conditions that occur across a stream of laminar flowing material that flows at a first level in at least one flow path of a tool, comprising: providing within at least one flow path of the tool an adjustable flow diverter device having a flow geometry that is adjustable in situ within a body of the tool to reposition the non-homogeneous conditions of the laminar flowing material to desired positions within the cross section of the flow path downstream of the adjustable flow diverter device; the adjustable flow diverter device including a first flow path portion and a second flow path portion; the first flow path portion having an interconnecting area and the second flow path portion having an interconnecting area; a third flow path portion connecting the interconnecting area of the first flow path portion and the interconnecting area of the second flow path portion, the third flow path portion having a structure which enables it to interconnect some or substantially the entire stream of laminar flowing material to and/or from a second flow level that is different from the flow level of at least one of the first and second flow path portions; and the flow geometry of the adjustable flow diverter device being adjustable in situ by moving the third flow path portion to one of multiple positions with respect to one of the interconnecting areas to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions; flowing a stream of laminar flowing material in the flow path in which the adjustable flow diverter device is located so that non-homogeneous melt conditions occur across laminates of the stream; and adjusting the flow geometry of the adjustable flow diverter device in situ within the tool body so that the non-homogeneous conditions of the laminar flowing material are repositioned to the desired positions within the cross section of the flow path of the tool. 2. A method according to claim 1 wherein the first flow path portion has an interconnecting area at about one end of the first flow path portion and the second flow path portion has an interconnecting area at about one end of the second flow path portion; the third flow path portion is rotatable, and the flow geometry of the adjustable flow diverter device is adjusted by rotating the rotatable flow path portion to one of multiple positions with respect to the interconnecting area of the first flow path portion and to one of multiple portions with respect to the interconnecting area of the second flow path portion to reposition the non-homogeneous conditions of the flowing material. 3. A method according to claim 1 wherein the third flow path portion is rotatable; the flow geometry of the adjustable flow diverter device is adjusted by rotating the rotatable flow path portion to one of multiple positions with respect to the interconnecting area of the first flow path portion and to one of multiple portions with respect to the interconnecting area of the second flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material; and one of the flow path portions at the intersection of the interconnecting area of the first flow path portion with the rotatable flow path portion has a first divergent flow path area and one of the flow paths at the intersection of the interconnecting area of the second flow path portion and the rotatable flow path portion has a second divergent flow path area. 4. A method according to claim 3 wherein the first divergent flow path is located on the interconnecting area of the first flow path portion and the second divergent flow path is located on the interconnecting area of the second flow path portion. 5. A method according to claim 3 wherein the first divergent flow path has a substantially arcuate shape and is located on the interconnecting area of the first flow path portion and the second divergent flow path has a substantially arcuate shape and is located on the interconnecting area of the second flow path portion. 6. A method according to claim 1 wherein the third flow path portion is rotatable and the method includes rotating the rotatable flow path portion to one of its multiple positions with respect to the interconnecting area of the first flow path to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material in a circumferential direction; and one of the flow path portions at the intersection of the interconnecting area of the first flow path portion with the rotatable flow path portion has a divergent flow path with respect to that flow path portion. 7. A method according to claim 6 wherein the divergent flow path is located on the first flow path portion. 8. A method according to claim 6 wherein the first divergent flow path has an approximately arcuate shape and is located on the first flow path portion. 9. A method according to claim 1 wherein the first flow path portion and the second flow path portion each have a flow path that splits into two branching flow path portions, each branching flow path portion having an interconnecting area at about one end of that branching flow path portion; the third flow path portion comprising a pair of rotatable flow path portions, each rotatable flow path portion connecting an interconnecting area of one of the branching flow path portions of the first flow path portion and an interconnecting area of a branching flow path portion of the second flow path portion; rotating each rotatable flow path portion to one of its multiple positions with respect to the interconnecting areas of the branching flow path portions of the first flow path portion and the second flow path portion that it intersects to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material, as the stream of laminar flowing material flows through the second flow level. 10. A method according to claim 1 wherein the first flow path portion and the second flow path portion each has a flow path that splits into two branching flow path portions, each branching flow path portion having an interconnecting area at about one end of that branching flow path portion; the third flow path portion comprises a pair of rotatable flow path portions, each rotatable flow path portion connecting an interconnecting area of one of the branching flow path portions of the first flow path portion and an interconnecting area of one of the branching flow path portions of the second flow path portion; rotating each rotatable flow path portion to one of its multiple positions with respect to the interconnecting areas of the branching flow path portions of the first flow path portion and the second flow path portion that it intersects to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material as the stream of laminar flowing material flows through the second flow level; a divergent flow path on one of the flow path portions at the intersection of each rotatable flow path portion with an interconnecting area of one of the branching flow path portions of the first flow path portion; and a divergent flow path on one of the flow path portions at the intersection of each rotatable flow path portion with an interconnecting area of one of the branching flow path portions of the second flow path portion. 11. A method according to claim 10 wherein the divergent flow paths at the intersection of each rotatable flow path portion with an interconnecting area of a branch of the first flow path portion are on the branch of the first flow path portion and the divergent flow paths at the intersection of each rotatable flow path portion with an interconnecting area of a branch of the second flow path portion are on the second flow path portion. 12. A method according to claim 10 wherein each interconnecting area has an approximately arcuate shape. 13. A method according to claim 1 wherein the first flow path portion has a flow path that has an interconnecting area at about one end of the first flow path portion; the third flow path portion comprises a movable flow path portion that moves in a direction substantially perpendicular to the flow path of the first flow path portion; the movable flow path portion connecting the interconnecting area of the first flow path portion with the second flow path portion; moving the movable flow path portion to one of multiple positions with respect to the interconnecting area of the first flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flow material as the stream of laminar flowing material flows through the second flow level. 14. A method according to claim 1 wherein the first flow path portion has a flow path that splits into two branching flow path portions and each branching flow path portion has an interconnecting area at about one end of that branching flow path portion; the third flow path portion comprises a movable flow path portion that moves in a direction substantially perpendicular to the flow path of the first flow path portion; the movable flow path portion connecting the interconnecting areas of the branching flow path portions with the second flow path portion; the movable flow path portion being movable to multiple positions with respect to the interconnecting areas of the branching flow path portions of the first flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material as the stream of laminar flowing material flows through the second flow level. 15. A method according to claim 1 in which the adjustable flow diverter device is located in line with the at least one flow path and is adjustable to split at least some of the stream of laminar flowing material into two repositioning flow paths, each of which is constructed to reposition the non-homogeneous melt conditions; the third flow path portion includes an in-line flow path that is in line with the at least one flow path, with the adjustable flow diverter device constructed to merge the in-line flow path with the two repositioning flow paths into a downstream flow path to adjust the distribution of non- homogeneous melt conditions; and the third flow path portion is adjustable to direct at least some of the stream of laminar flowing material to the in-line flow path. 16. A method accordingly to claim 1 wherein the adjustable flow diverter device is located in line with the at least one flow path and can split at least some of the stream of laminar flowing material into two separable streams of laminar flowing material that are recombined downstream into repositioned non-homogeneous melt conditions; the third flow path portion including a vertically adjustable pin; and the method includes adjusting the pin to control the repositioning of the non-homogeneous melt conditions to a desired position. 17. A method according to claim 1 wherein the adjustable flow diverter is located in line of the at least one flow path and splits at least some of the stream of laminar flowing material into two separate streams that are recombined downstream to form repositioned, non-homogeneous melt conditions; and the third flow path portion being adjustable to enable at least some of the stream of laminar flowing material to pass in line with the at least one flow path without being split to control the repositioning of the non-homogeneous melt conditions to desired positions. 18. A method according to claim 1 wherein the adjustable flow diverter device is located in line with the at least one flow path and includes a vertically adjustable pin that can split at least some of the stream of laminar flowing material into two separated streams of laminar flowing material and can cause the two separated streams to flow to a second flow level and to be recombined downstream into repositioned non-homogeneous melt conditions; and vertically adjusting the adjustable pin to control the repositioning of the non-homogeneous melt conditions to a desired position. 19. A method according to claim 1 wherein the adjustable flow diverter device includes a controller actuator that provides a closed loop automatic adjustment of the adjustable flow geometry of the diverter device or a controller actuator that allows for an open loop adjustment of the adjustable flow geometry of the diverter device and the flow geometry of the adjustable flow diverter device is adjusted by operation of the controller actuator. 20. A method according to claim 1 in which the adjustable flow diverter device includes a manually operable actuator and the flow geometry of the diverter device is adjusted through the use of the manually operable actuator. 21. A method according to claim 1 in which the adjustable flow diverter device includes a machine driven actuator and the flow geometry of the diverter device is adjusted by the operation of the machine. 22. A method according to claim 1 in which the adjustable flow diverter device includes an actuator comprising a pneumatic, hydraulic, mechanical or electrical mechanism attached to the adjustable flow geometry of the diverter device and the flow geometry is adjusted by operation of the mechanism. 23. A method according to claim 1 in which the adjustable flow diverter includes an actuator that adjusts the adjustable flow geometry over time to change the repositioning of the non-homogeneous conditions while material is flowing. 24. A method according to claim 1 that includes one or more pressure transducers or thermocouples located at various positions along the flow path to sense fluid pressure or temperature variations, respectively, along the flow path and flow geometry is adjusted over time in response to fluid pressure variations or temperature variations to change the fluid flow repositioning while material is flowing. 25. A method according to claim 1wherein the adjustable flow diverter device includes a controller actuator that provides a closed loop adjustment of the adjustable flow geometry of the diverter device or a controller that allows for an open loop adjustment of the adjustable flow geometry of the diverter device, either controller actuator being operable in response to one or more pressure or mold process timing or temperature signals to adjust the flow front of the stream of laminar flowing material. 26. A method according to claim 1 wherein the tool is a hot runner mold. 27. A method according to claim 1 wherein the tool is a hot runner mold and the tool is constructed to locate the adjustable flow diverter device in at least one manifold, hot nozzle, hot drop or valve gate. 28. A tool including an adjustable flow diverter device for controlling non-homogeneous melt conditions which occur in a direction across the flow path of laminates of a stream of laminar flowing material, comprising: a tool body having at least one product forming cavity and at least one flow path through which a stream of laminar flowing material flows to fill the at least one product forming area; and an adjustable flow diverter device located in at least a portion of the at least one flow path and in line of the at least one flow path and including a first component having a discontinuous flow directing section with a discontinuous divergent path and a second component having a flow channel portion that connects the discontinuous flow directing section with a downstream flow path, the second component being relatively rotatable in situ relative to the first component to precisely reposition the non-homogeneous conditions of laminar flowing material in a circumferential direction to a position having a desired asymmetrical or symmetrical melt condition relative to a downstream branching runner or the at least one product forming area. 29. The tool according to claim 28, wherein the discontinuous flow directing section has a branching Y path. 30. The tool according to claim 28, wherein the discontinuous flow directing section includes at least two divergent paths. 31. The tool according to claim 28, wherein the discontinuous flow directing section includes at least one branch. 32. The tool according to claim 28, wherein the adjustable flow diverter is located inline of the runner and splits the stream of laminar flowing material into two separated streams that are recombined downstream into a repositioned non-homogeneous melt condition, the adjustable flow diverter controlling the repositioning to a desired position. 33. The tool according to claim 32, wherein the adjustable flow diverter is configured to enable at least some of the stream of laminar flowing material to pass through the adjustable inline flow diverter without being split. 34. A method of adjusting the rotational positioning in the circumferential direction of multiple streams of laminar flowing fluid, comprising: positioning non-homogeneous melt conditions within the individual streams of laminar flowing material toward a desirable position by directing the fluid through an adjustable flow diverter device; recombining the melt streams into a single melt stream; and adjusting the flow geometry of the flow diverter device in situ to achieve a desirable non-homogeneous melt distribution within the combined streams of laminar flowing fluid as a result of relative movement or replacement of a portion of the flow diverter device to directly control the amount of rotation occurring in the circumferential direction within one or more of the streams of laminar flowing fluid. 35. A tool including an adjustable flow diverter device for controlling non-homogeneous conditions which occur in a direction across a flow path of laminates of a stream of laminar flowing material, comprising: at least one flow path through which a stream of laminar flowing material flows at a first flow level; and an adjustable flow diverter device located in at least a portion of the at least one flow path in which the non-homogeneous conditions occur across the stream of laminar flowing material, the adjustable flow diverter device including a first flow path portion and a second flow path portion; the first flow path portion having an interconnecting area and the second flow path portion having an interconnecting area; a third flow path portion connecting the interconnecting area of the first flow path portion and the interconnecting area of the second flow path portion, the third flow path portion having a structure which enables it to interconnect some or substantially the entire stream of laminar flowing material to and/or from a second flow level that is different from the flow level of at least one of the first and second flow path positions, the third flow path portion being adjustable in situ with respect to at least one of the interconnecting areas to adjust the flow path geometry of the diverter device to reposition the non-homogeneous conditions of the laminar flowing material in a circumferential direction to desired positions having a desired asymmetrical or symmetrical melt conditions on a cross section of a flow path downstream of the adjustable flow diverter device. 36. A tool according to claim 35 wherein the first flow path portion has an interconnecting area at about one end of the first flow path portion and the second flow path portion has an interconnecting area at about one end of the second flow path portion; the third flow path portion connecting the interconnecting area of the first flow path portion and the interconnecting area of the second flow path portion; the third flow path portion being rotatable to multiple positions with respect to at least one of the interconnecting areas to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material in a circumferential direction. 37. A tool according to claim 35 wherein the first flow path portion has an interconnecting area and the second flow path portion has an interconnecting area; the third flow path portion connecting the interconnecting area of the first flow path portion and the interconnecting area of the second flow path portion; the third flow path portion being rotatable to multiple positions with respect to the interconnecting area of the first flow path portion and to multiple positions with respect to the interconnecting area of the second flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material in a circumferential direction. 38. A tool according to claim 35 wherein the first flow path portion has an interconnecting area and the second flow path portion has an interconnecting area; the third flow path portion connecting the interconnecting area of the first flow path portion and the interconnecting area of the second flow path portion; the third flow path portion being rotatable to multiple positions with respect to the interconnecting area of the first flow path portion and to multiple portions with respect to the interconnecting area of the second flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material in a circumferential direction; one of the flow path portions at the intersection of the interconnecting area of the first flow path portion with the rotatable flow path portion having a first divergent flow path area, and one of the flow paths at the intersection of the interconnecting area of the second flow path portion and the rotatable flow path portion having a second divergent flow path area. 39. A tool according to claim 38 wherein the first divergent flow path is located on the interconnecting area of the first flow path portion and the second divergent flow path is located on the interconnecting area of the second flow path portion. 40. A tool according to claim 38 wherein the first divergent flow path has a substantially arcuate shape and is located on the interconnecting area of the first flow path portion and the second divergent flow path has a substantially arcuate shape and is located on the interconnecting area of the second flow path portion. 41. A tool according to claim 35, wherein the third flow path portion is rotatable to multiple positions with respect to the interconnecting area of the first flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material in a circumferential direction, one of the flow path portions at the intersection of the interconnecting area of the first flow path portion with the third flow path portion having a divergent flow path with respect to that flow path portion. 42. A tool according to claim 41 wherein the divergent flow path is located on the first flow path portion. 43. A tool according to claim 41 wherein the divergent flow path has an approximately arcuate shape and is located on the first flow path portion. 44. A tool according to claim 35 wherein the first flow path portion and the second flow path portion each have a flow path that splits into two branching flow path portions, each branching flow path portion having an interconnecting area; the third flow path portion comprising a pair of rotatable flow path portions, each rotatable flow path portion connecting an interconnecting area of one of the branching flow path portions of the first flow path portion and an interconnecting area of one of the branching flow path portions of the second flow path portion; each rotatable flow path portion being rotatable to multiple positions with respect to the interconnecting areas of the branching flow path portions of the first flow path portion and the second flow path portion that it intersects to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material as the stream of laminar flowing material flows through the second flow level. 45. A tool according to claim wherein the first flow path portion and the second flow path portion each have a flow path that splits into two branching flow path portions, each branching flow path portion having an interconnecting area at about one end of that branching flow path portion; the third flow path portion comprising a pair of rotatable flow path portions, each rotatable flow path portion connecting an interconnecting area of one of the branching flow path portions of the first flow path portion and an interconnecting area of one of the branching flow path portions of the second flow path portion; each rotatable flow path portion being rotatable to multiple positions with respect to the interconnecting areas of the branching flow path portions of the first flow path portion and the second flow path portion that it intersects to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material as the stream of laminar flowing material flows through the second flow level; a divergent flow path on one of the flow path portions at the intersection of each rotatable flow path portion with an interconnecting area of one of the branching flow path portions of the first flow path portion; and a divergent flow path on one of the flow path portions at the intersection of each rotatable flow path portion with an interconnecting area of one of the branching flow path portions of the second flow path portion. 46. A tool according to claim 45 wherein the divergent flow paths at the intersection of each rotatable flow path portion with an interconnecting area of a branch of the first flow path portion are on the branch of the first flow path portion and the divergent flow paths at the intersection of each rotatable flow path portion with an interconnecting area of a branch of the second flow path portion are on the second flow path portion. 47. A tool according to claim 45 wherein each interconnecting area has an approximately arcuate shape. 48. A tool according to claim 35 wherein the first flow path portion has a flow path that has an interconnecting area at about one end of the first flow path portion; the third flow path portion comprises a movable flow path portion that moves in a direction substantially perpendicular to the flow path of the first flow path portion; the movable flow path portion connecting the interconnecting area of the first flow path portion with the second flow path portion; the movable flow path portion being movable to multiple positions with respect to the interconnecting area of the first flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flow material as the stream of laminar flowing material flows through the second flow level. 49. A tool according to claim 35 wherein the first flow path portion has a flow path that splits into two branching flow path portions, each branching flow path portion having an interconnecting area at about one end of that branching flow path portion; the third flow path portion comprises a movable flow path portion that moves in a direction substantially perpendicular to the flow path of the first flow path portion; the movable flow path portion connecting the interconnecting areas of the branching flow path portions with the second flow path portion; the movable flow path portion being movable to multiple positions with respect to the interconnecting areas of the branching flow path portions of the first flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material as the stream of laminar flowing material flows through the second flow level. 50. A tool according to claim 35 in which the adjustable flow diverter device is located in line with the at least one flow path and is adjustable to split at least some of the stream of laminar flowing material into two repositioning flow paths, each of which is constructed to reposition the non-homogeneous melt conditions; the third flow path portion includes an in-line flow path that is in line with the at least one flow path, is adjustable to direct at least some of the stream of laminar flowing material to the in-line flow path and is constructed to merge the in-line flow path with the two repositioning flow paths into a downstream flow path to adjust the distribution of non-homogeneous melt conditions. 51. A tool accordingly to claim 35 wherein the adjustable flow diverter device is located in line with the at least one flow path and can split at least some of the stream of laminar flowing material into two separable streams that are recombined downstream into repositioned non-homogeneous melt conditions, the third flow path portion including a pin that is adjustable vertically to control the repositioning of the non-homogeneous melt conditions to a desired position. 52. A tool according to claim 35 wherein the adjustable flow diverter is located in line of the at least one flow path and splits at least some of the stream of laminar flowing material into two separate streams that are recombined downstream to form repositioned non-homogeneous melt conditions, the third flow path portion being adjustable to enable at least some of the stream of laminar flowing material to pass in line with the at least one flow path without being split, the adjustable flow diverter controlling the repositioning to a desired position. 53. A tool according to claim 35 wherein the adjustable flow diverter device is located in line with the at least one flow path and includes a vertically adjustable pin that can split at least some of the stream of laminar flowing material into two separated streams and can cause the two separated streams to flow to a second flow level and to be recombined downstream into repositioned non-homogeneous melt conditions, the vertically adjustable pin controlling the repositioning of the non-homogeneous melt conditions to a desired position. 54. A tool according to claim 35 wherein the adjustable flow diverter device includes a controller actuator that provides a closed loop automatic adjustment of the adjustable flow geometry of the diverter device or a controller actuator that allows for an open loop adjustment of the adjustable flow geometry of the diverter device. 55. A tool according to claim 35 in which the adjustable flow diverter device includes a manually operable actuator to adjust the adjustable flow geometry of the diverter device. 56. A tool according to claim 35 in which the adjustable flow diverter device includes a machine driven actuator to adjust the adjustable flow geometry of the diverter device. 57. A tool according to claim 35 in which the adjustable flow diverter device includes an actuator comprising a pneumatic, hydraulic, mechanical or electrical mechanism to adjust the adjustable flow geometry of the diverter device. 58. A tool according to claim 35 in which the adjustable flow diverter includes an actuator that adjusts the adjustable flow geometry over time to change the repositioning of the non-homogeneous conditions while material is flowing. 59. A tool according to claim 35 that includes one or more pressure transducers or thermocouples located at various positions along the flow path to sense fluid pressure or temperature variations, respectively, along the flow path so as to enable the flow diverter device to adjust the adjustable flow geometry over time to change the fluid flow repositioning while material is flowing. 60. A tool according to claim 35 wherein the adjustable flow diverter device includes a controller actuator that provides a closed loop adjustment of the adjustable flow geometry of the diverter device or a controller that allows for an open loop adjustment of the adjustable flow geometry of the diverter device, either controller actuator being operable in response to one or more pressure or mold process timing or temperature signals to adjust the flow front of the stream of laminar flowing material. 61. A tool according to claim 35 wherein the tool is a hot runner mold. 62. A tool according to claim 35 wherein the tool is a hot runner mold and the adjustable flow diverter is located in at least one manifold, hot nozzle, hot drop or valve gate. 63. An insert for a tool having at least one flow path through which a stream of laminar flowing material flows at a first flow level, the insert comprising: an adjustable flow diverter device located in at least a portion of the at least one flow path in which non-homogeneous conditions occur across the stream of laminar flowing material, the adjustable flow diverter device including a first flow path portion and a second flow path portion; the first flow path portion having an interconnecting area and the second flow path portion having an interconnecting area; a third flow path portion connecting the interconnecting area of the first flow path portion and the interconnecting area of the second flow path portion, the third flow path portion having a structure which enables it to interconnect some or substantially the entire stream of laminar flowing material to and/or from a second flow level that is different from the flow level of at least one of the first and second flow path positions, the third flow path portion being adjustable in situ with respect to at least one of the interconnecting areas to adjust the flow path geometry of the diverter device to reposition the non-homogeneous conditions of the laminar flowing material in a circumferential direction to desired positions having a desired asymmetrical or symmetrical melt conditions on a cross section of a flow path downstream of the adjustable flow diverter device. 64. An insert for a tool according to claim 63 wherein the first flow path portion has an interconnecting area at about one end of the first flow path portion and the second flow path portion has an interconnecting area at about one end of the second flow path portion; the third flow path portion connecting the interconnecting area of the first flow path portion and the interconnecting area of the second flow path portion; the third flow path portion being rotatable to multiple positions with respect to at least one of the interconnecting areas to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material in a circumferential direction. 65. An insert for a tool according to claim 63 wherein the first flow path portion has an interconnecting area and the second flow path portion has an interconnecting area; the third flow path portion connecting the interconnecting area of the first flow path portion and the interconnecting area of the second flow path portion: the third flow path portion being rotatable to multiple positions with respect to the interconnecting area of the first flow path portion and to multiple positions with respect to the interconnecting area of the second flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material in a circumferential direction. 66. An insert for a tool according to claim 63 wherein the first flow path portion has an interconnecting area and the second flow path portion has an interconnecting area; the third flow path portion connecting the interconnecting area of the first flow path portion and the interconnecting area of the second flow path portion; the third flow path portion being rotatable to multiple positions with respect to the interconnecting area of the first flow path portion and to multiple portions with respect to the interconnecting area of the second flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material in a circumferential direction; one of the flow path portions at the intersection of the interconnecting area of the first flow path portion with the rotatable flow path portion having a first divergent flow path area, and one of the flow paths at the intersection of the interconnecting area of the second flow path portion and the rotatable flow path portion having a second divergent flow path area. 67. An insert for a tool according to claim 66 wherein the first divergent flow path is located on the interconnecting area of the first flow path portion and the second divergent flow path is located on the interconnecting area of the second flow path portion. 68. An insert for a tool according to claim 66 wherein the first divergent flow path has a substantially arcuate shape and is located on the interconnecting area of the first flow path portion and the second divergent flow path has a substantially arcuate shape and is located on the interconnecting area of the second flow path portion. 69. An insert for a tool according to claim 63, wherein the third flow path portion is rotatable to multiple positions with respect to the interconnecting area of the first flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material in a circumferential direction, one of the flow path portions at the intersection of the interconnecting area of the first flow path portion with the third flow path portion having a divergent flow path with respect to that flow path portion. 70. An insert for a tool according to claim 69 wherein the divergent flow path is located on the first flow path portion. 71. An insert for a tool according to claim 69 wherein the divergent flow path has an approximately arcuate shape and is located on the first flow path portion. 72. An insert for a tool according to claim 63 wherein the first flow path portion and the second flow path portion each have a flow path that splits into two branching flow path portions, each branching flow path portion having an interconnecting area; the third flow path portion comprising a pair of rotatable flow path portions, each rotatable flow path portion connecting an interconnecting area of one of the branching flow path portions of the first flow path portion and an interconnecting area of one of the branching flow path portions of the second flow path portion; each rotatable flow path portion being rotatable to multiple positions with respect to the interconnecting areas of the branching flow path portions of the first flow path portion and the second flow path portion that it intersects to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material as the stream of laminar flowing material flows through the second flow level. 73. An insert for a tool according to claim 63 wherein the first flow path portion and the second flow path portion each have a flow path that splits into two branching flow path portions, each branching flow path portion having an interconnecting area at about one end of that branching flow path portion; the third flow path portion comprising a pair of rotatable flow path portions, each rotatable flow path portion connecting an interconnecting area of one of the branching flow path portions of the first flow path portion and an interconnecting area of one of the branching flow path portions of the second flow path portion: each rotatable flow path portion being rotatable to multiple positions with respect to the interconnecting areas of the branching flow path portions of the first flow path portion and the second flow path portion that it intersects to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material as the stream of laminar flowing material flows through the second flow level; a divergent flow path on one of the flow path portions at the intersection of each rotatable flow path portion with an interconnecting area of one of the branching flow path portions of the first flow path portion; and a divergent flow path on one of the flow path portions at the intersection of each rotatable flow path portion with an interconnecting area of one of the branching flow path portions of the second flow path portion. 74. An insert for a tool according to claim 73 wherein the divergent flow paths at the intersection of each rotatable flow path portion with an interconnecting area of a branch of the first flow path portion are on the branch of the first flow path portion and the divergent flow paths at the intersection of each rotatable flow path portion with an interconnecting area of a branch of the second flow path portion are on the second flow path portion. 75. An insert for a tool according to claim 73 wherein each interconnecting area has an approximately arcuate shape. 76. An insert for a tool according to claim 63 wherein the first flow path portion has a flow path that has an interconnecting area at about one end of the first flow path portion; the third flow path portion comprises a movable flow path portion that moves in a direction substantially perpendicular to the flow path of the first flow path portion; the movable flow path portion connecting the interconnecting area of the first flow path portion with the second flow path portion; the movable flow path portion being movable to multiple positions with respect to the interconnecting area of the first flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flow material as the stream of laminar flowing material flows through the second flow level. 77. An insert for a tool according to claim 63 wherein the first flow path portion has a flow path that splits into two branching flow path portions, each branching flow path portion having an interconnecting area at about one end of that branching flow path portion; the third flow path portion comprises a movable flow path portion that moves in a direction substantially perpendicular to the flow path of the first flow path portion; the movable flow path portion connecting the interconnecting areas of the branching flow path portions with the second flow path portion; the movable flow path portion being movable to multiple positions with respect to the interconnecting areas of the branching flow path portions of the first flow path portion to adjust the flow geometry of the diverter device to reposition the non-homogeneous conditions of the flowing material as the stream of laminar flowing material flows through the second flow level. 78. An insert for a tool according to claim 63 in which the adjustable flow diverter device is located in line with the at least one flow path and is adjustable to split at least some of the stream of laminar flowing material into two repositioning flow paths, each of which is constructed to reposition the non-homogeneous melt conditions; the third flow path portion includes an in-line flow path that is in line with the at least one flow path, is adjustable to direct at least some of the stream of laminar flowing material to the in-line flow path and is constructed to merge the in-line flow path with the two repositioning flow paths into a downstream flow path to adjust the distribution of non-homogeneous melt conditions. 79. An insert for a tool accordingly to claim 63 wherein the adjustable flow diverter device is located in line with the at least one flow path and can split at least some of the stream of laminar flowing material into two separable streams that are recombined downstream into repositioned non-homogeneous melt conditions, the third flow path portion including a pin that is adjustable vertically to control the repositioning of the non-homogeneous melt conditions to a desired position. 80. An insert for a tool according to claim 63 wherein the adjustable flow diverter is located in line of the at least one flow path and splits at least some of the stream of laminar flowing material into two separate streams that are recombined downstream to form repositioned non-homogeneous melt conditions, the third flow path portion being adjustable to enable at least some of the stream of laminar flowing material to pass in line with the at least one flow path without being split, the adjustable flow diverter controlling the repositioning to a desired position. 81. An insert for a tool according to claim 63 wherein the adjustable flow diverter device is located in line with the at least one flow path and includes a vertically adjustable pin that can split at least some of the stream of laminar flowing material into two separated streams and can cause the two separated streams to flow to a second flow level and to be recombined downstream into repositioned non-homogeneous melt conditions, the vertically adjustable pin controlling the repositioning of the non-homogeneous melt conditions to a desired position. 82. An insert for a tool according to claim 63 wherein the adjustable flow diverter device includes a controller actuator that provides a closed loop automatic adjustment of the adjustable flow geometry of the diverter device or a controller actuator that allows for an open loop adjustment of the adjustable flow geometry of the diverter device. 83. An insert for a tool according to claim 63 in which the adjustable flow diverter device includes a manually operable actuator to adjust the adjustable flow geometry of the diverter device. 84. An insert for a tool according to claim 63 in which the adjustable flow diverter device includes a machine driven actuator to adjust the adjustable flow geometry of the diverter device. 85. An insert for a tool according to claim 63 in which the adjustable flow diverter device includes an actuator comprising a pneumatic, hydraulic, mechanical or electrical mechanism to adjust the adjustable flow geometry of the diverter device. 86. An insert for a tool according to claim 63 in which the adjustable flow diverter includes an actuator that adjusts the adjustable flow geometry over time to change the repositioning of the non-homogeneous conditions while material is flowing. 87. An insert for a tool according to claim 63 that includes one or more pressure transducers or thermocouples located at various positions along the flow path to sense fluid pressure or temperature variations, respectively, along the flow path so as to enable the flow diverter device to adjust the adjustable flow geometry over time to change the fluid flow repositioning while material is flowing. 88. An insert for a tool according to claim 63 wherein the adjustable flow diverter device includes a controller actuator that provides a closed loop adjustment of the adjustable flow geometry of the diverter device or a controller that allows for an open loop adjustment of the adjustable flow geometry of the diverter device, either controller actuator being operable in response to one or more pressure or mold process timing or temperature signals to adjust the flow front of the stream of laminar flowing material. 89. An insert for a tool according to claim 63 wherein the tool is a hot runner mold. 90. An insert for a tool according to claim 63 wherein the tool is a hot runner mold and the adjustable flow diverter is located in at least one manifold, hot nozzle, hot drop or valve gate.
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