Dies for making extruded synthetic wood and methods relating thereto
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B29C-047/30
B29C-047/00
B29C-047/92
B29C-047/14
출원번호
US-0569629
(2009-09-29)
등록번호
US-8337191
(2012-12-25)
발명자
/ 주소
Keller, Brian David
Dostal, David Frank
England, Alfred Bruce
출원인 / 주소
Strandex Corporation
대리인 / 주소
Sara, Esq., Charles S.
인용정보
피인용 횟수 :
2인용 특허 :
12
초록▼
The present invention is directed to extrusion dies for making extruded synthetic wood and methods relating thereto. The dies include adapter dies, transition dies, stranding dies, and molding dies. The adapter dies include a channel with a restricted cross-sectional area. The stranding dies include
The present invention is directed to extrusion dies for making extruded synthetic wood and methods relating thereto. The dies include adapter dies, transition dies, stranding dies, and molding dies. The adapter dies include a channel with a restricted cross-sectional area. The stranding dies include a plurality of non-uniform channels that differ in length, cross-sectional area, cross-sectional shape, or combinations thereof. The transition dies are coordinately configured with the stranding die to adjust the flow rate of the extrudate. Particular configurations of dies upstream of the molding die allow for higher compression ratios in the molding die than previously feasible. Each of the dies described herein may be used individually with standard dies known in the art. Alternatively, the dies may be used in combination to form integrated units. The dies described herein allow for making stronger, more consistent synthetic wood at greater output rates than previously possible.
대표청구항▼
1. An apparatus comprising: a source of extrudate flow;a stranding die configured to receive extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to th
1. An apparatus comprising: a source of extrudate flow;a stranding die configured to receive extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die; anda transition die configured and dimensioned to connect to the stranding die, the transition die including: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice and having an inner surface, wherein the channel includes a tapered zone that decreases in cross-sectional area from that of the front orifice to that of the rear orifice, the channel further includes a space between the inner surface of the tapered zone and the front perforated surface of the stranding die that defines a manifold, and the manifold is coordinately configured and dimensioned with a length and/or cross-sectional area of the channels in the plurality of non-uniform channels in the stranding die to increase uniformity of extrudate flow relative to a stranding die having channels of equal length and cross-sectional area. 2. The apparatus of claim 1 wherein the transition and stranding dies are configured such that a direction of flow of extrudate entering the transition die is at an angle relative to a direction of flow of extrudate entering the stranding die. 3. The apparatus of claim 1 wherein the transition and stranding dies are included in a straight extruder system and the tapered zone defines an annular taper. 4. The apparatus of claim 1 further comprising an adapter die dimensioned and configured to connect to the transition die comprising: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice, wherein the channel includes a restricted zone. 5. The apparatus of claim 1 wherein the stranding die is configured and dimensioned to adjust flow of extrudate therethrough and the plurality of non-uniform channels includes channels having differing lengths and/or differing cross-sectional area. 6. The apparatus of claim 1 wherein the plurality of non-uniform channels range in cross-sectional area from a narrowest channel to a widest channel by a factor of at least about 1.01. 7. The apparatus of claim 1 wherein the plurality of non-uniform channels includes channels having centerlines with uniform distances between the centerlines. 8. The apparatus of claim 1 wherein the plurality of non-uniform channels includes channels having centerlines with varying distances between the centerlines. 9. The apparatus of claim 1 wherein the sloping, front perforated surface consists of a consistent slope. 10. The apparatus of claim 1 further including an extruder configured relative to the stranding die such that a direction of flow of extrudate in the extruder is at an angle relative to a direction of flow of extrudate in the stranding die. 11. The apparatus of claim 1 wherein the sloping, front perforated surface comprises variable slope. 12. The apparatus of claim 1 wherein a center of the plurality of non-uniform channels has channels with a greater cross-sectional area than channels in a periphery of the plurality of non-uniform channels. 13. The apparatus of claim 1 wherein a periphery of the plurality of non-uniform channels has channels with a greater cross-sectional area than channels in a center of the plurality of non-uniform channels. 14. The apparatus of claim 1 wherein channels in the plurality of non-uniform channels vary in distance from the source of extrudate flow and wherein the channels decrease in length as the distance from the source of extrudate flow increases. 15. The apparatus of claim 1 wherein the plurality of non-uniform channels includes channels having differing cross-sectional area, and wherein distances between the channels in the plurality of non-uniform channels is as constant as possible within the limits of geometry. 16. The apparatus of claim 1 wherein the plurality of non-uniform channels includes channels substantially circular in cross section and channels substantially non-circular in cross section. 17. The apparatus of claim 16 wherein the channels substantially non-circular in cross section interrupt a plane defined by rows of the channels substantially circular in cross section. 18. An apparatus comprising: a source of extrudate flow;a stranding die configured to receive extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die; anda molding die configured and dimensioned to connect to the stranding die, the molding die including: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice, wherein a ratio of cross-sectional area of the front orifice to cross-sectional area of the rear orifice defines a compression ratio and the compression ratio is greater than about 1.5:1. 19. An apparatus comprising: a source of extrudate flow;a stranding die configured to receive extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die;a transition die configured and dimensioned to connect to the stranding die, the transition die including: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice and having an inner surface, wherein the channel includes a tapered zone that decreases in cross-sectional area from that of the front orifice to that of the rear orifice, the channel further includes a space between the inner surface of the tapered zone and the front perforated surface of the stranding die that defines a manifold, and the manifold is coordinately configured and dimensioned with a length and/or cross-sectional area of the channels in the plurality of non-uniform channels in the stranding die to increase flow rate of extrudate in a center of a cross-sectional profile of the extrudate relative to a periphery of the cross-sectional profile of the extrudate; anda molding die configured and dimensioned to connect to the stranding die, the molding die including: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice, wherein a ratio of cross-sectional area of the front orifice to cross-sectional area of the rear orifice defines a compression ratio and the compression ratio is greater than about 1.5:1. 20. An apparatus comprising: a source of extrudate flow;a stranding die configured to receive extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die; andan adapter die including: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice, wherein the channel includes a restricted zone with a cross-sectional area less than a cross-sectional area of the rear orifice, wherein the plurality of non-uniform channels in the stranding die is dimensioned and configured to increase uniformity of extrudate flow relative to a stranding die having channels of equal length and cross-sectional area. 21. A process comprising extruding a cellulosic plastic composite extrudate with an apparatus, the apparatus comprising: a source of extrudate flow;a stranding die configured to receive the extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed the extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die, andan adapter die, wherein the adapter die includes: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice, wherein the channel includes a restricted zone with a cross-sectional area less than a cross-sectional area of the rear orifice, wherein the plurality of non-uniform channels in the stranding die is dimensioned and configured to generate uniform flow of extrudate from the rear perforated surface of the stranding die. 22. A process comprising extruding a cellulosic plastic composite extrudate with an apparatus, the apparatus comprising: a source of extrudate flow;a stranding die configured to receive the extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed the extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die, anda molding die, wherein the molding die includes: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice, wherein a ratio of cross-sectional area of the front orifice to cross-sectional area of the rear orifice defines a compression ratio and the compression ratio is greater than about 1.5:1. 23. A process comprising extruding a cellulosic plastic composite extrudate with an apparatus, the apparatus comprising: a source of extrudate flow;a stranding die configured to receive the extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed the extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die;a transition die, wherein the transition die includes: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice and having an inner surface, wherein the channel includes a tapered zone that decreases in cross-sectional area from that of the front orifice to that of the rear orifice, the channel further includes a space between the inner surface of the tapered zone and the front perforated surface of the stranding die that defines a manifold, and the manifold is coordinately configured and dimensioned with a length and/or cross-sectional area of the channels in the plurality of non-uniform channels in the stranding die to increase flow rate of extrudate in a center of a cross-sectional profile of the extrudate relative to a periphery of the cross-sectional profile of the extrudate; anda molding die, wherein the molding die includes: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice, wherein a ratio of cross-sectional area of the front orifice to cross-sectional area of the rear orifice defines a compression ratio and the compression ratio is greater than about 1.5:1. 24. A process comprising extruding a cellulosic plastic composite extrudate with an apparatus, the apparatus comprising: a source of extrudate flow;a stranding die configured to receive the extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed the extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die, anda transition die, wherein the transition die includes: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice and having an inner surface, wherein the channel includes a tapered zone that decreases in cross-sectional area from that of the front orifice to that of the rear orifice, the channel further includes a space between the inner surface of the tapered zone and the front perforated surface of the stranding die that defines a manifold, and the manifold is coordinately configured and dimensioned with a length and/or cross-sectional area of individual channels in the plurality of non-uniform channels in the stranding die to increase uniformity of extrudate flow relative to a stranding die having channels of equal length and cross-sectional area. 25. The process of claim 24 wherein a periphery of the plurality of non-uniform channels has channels with a greater cross-sectional area than channels in a center of the plurality of non-uniform channels. 26. The process of claim 24 wherein a center of the plurality of non-uniform channels has channels with a greater cross-sectional area than channels in a periphery of the plurality of non-uniform channels. 27. The process of claim 24 wherein the sloping, front perforated surface comprises variable slope. 28. The process of claim 24 wherein the apparatus further comprises a transition die, wherein the transition and stranding dies are configured such that a direction of flow of extrudate entering the transition die is at an angle relative to a direction of flow of extrudate entering the stranding die. 29. The process of claim 24 wherein the sloping, front perforated surface consists of a consistent slope. 30. The process of claim 24 wherein the plurality of non-uniform channels range in cross-sectional area from a narrowest channel to a widest channel by a factor of at least about 1.01. 31. The process of claim 24 wherein the stranding die is configured and dimensioned to adjust flow of extrudate therethrough and the plurality of non-uniform channels includes channels having differing lengths and/or differing cross-sectional area. 32. The apparatus of claim 24 wherein the plurality of non-uniform channels includes channels having centerlines with uniform distances between the centerlines. 33. The apparatus of claim 24 wherein the plurality of non-uniform channels includes channels having centerlines with varying distances between the centerlines. 34. The process of claim 24 wherein the transition and stranding dies are configured such that a direction of flow of extrudate entering the transition die is at an angle relative to a direction of flow of extrudate entering the stranding die. 35. The process of claim 24 wherein the apparatus further comprises a transition die, and wherein the transition and stranding dies are included in a straight extruder system and the tapered zone defines an annular taper. 36. The process of claim 24 wherein the apparatus further comprises an adapter die, wherein the adapter die includes: a front orifice;a rear orifice; anda channel connecting the front orifice to the rear orifice, wherein the channel includes a restricted zone. 37. The process of claim 24 wherein the plurality of non-uniform channels includes channels substantially circular in cross section and channels substantially non-circular in cross section, wherein the channels substantially non-circular in cross section interrupt a plane defined by rows of the channels substantially circular in cross section. 38. A process comprising extruding a cellulosic plastic composite extrudate with an apparatus, the apparatus comprising: a source of extrudate flow; anda stranding die configured to receive the extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed the extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die, and wherein the variable slope defines a concave perforated surface on the front perforated surface of the stranding die with a center portion of the concave perforated surface retracting away from the source of extrudate flow further than a periphery portion of the concave perforated surface. 39. The process of claim 38 wherein the plurality of non-uniform channels range in length from a smallest length to a greatest length by a factor of at least about 1.01. 40. A process comprising extruding a cellulosic plastic composite extrudate with an apparatus, the apparatus comprising: a source of extrudate flow; anda stranding die configured to receive the extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed the extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die, and wherein the variable slope defines a convex perforated surface on the front perforated surface with a center portion of the convex perforated surface extending toward the source of extrudate flow further than a periphery portion of the convex perforated surface. 41. The process of claim 40 wherein the plurality of non-uniform channels range in length from a smallest length to a greatest length by a factor of at least about 1.01. 42. An apparatus comprising: a source of extrudate flow; anda stranding die configured to receive extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die, wherein the sloping, front perforated surface comprises variable slope, and wherein the variable slope defines a convex perforated surface on the front perforated surface of the stranding die with a center portion of the convex perforated surface extending toward the source of extrudate flow further than a periphery portion of the convex perforated surface. 43. The apparatus of claim 42 wherein the plurality of non-uniform channels range in length from a smallest length to a greatest length by a factor of at least about 1.01. 44. An apparatus comprising: a source of extrudate flow; anda stranding die configured to receive extrudate from the source of extrudate flow, including: a sloping, front perforated surface;a rear perforated surface; anda plurality of non-uniform channels extending from the front perforated surface to the rear perforated surface,wherein the source of extrudate flow is configured with respect to the stranding die to feed extrudate against the front perforated surface and through the plurality of non-uniform channels of the stranding die, wherein the sloping, front perforated surface comprises variable slope, and wherein the variable slope defines a concave perforated surface on the front perforated surface of the stranding die with a center portion of the concave perforated surface retracting away from the source of extrudate flow further than a periphery portion of the concave perforated surface. 45. The apparatus of claim 44 wherein a center of the plurality of non-uniform channels has channels with a greater cross-sectional area than channels in a periphery of the plurality of non-uniform channels. 46. The apparatus of claim 44 wherein the plurality of non-uniform channels range in length from a smallest length to a greatest length by a factor of at least about 1.01. 47. The apparatus of claim 1 wherein the plurality of non-uniform channels includes channels substantially circular in cross section and channels substantially non-circular in cross section, wherein the channels substantially non-circular in cross section interrupt a plane defined by rows of the channels substantially circular in cross section.
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이 특허에 인용된 특허 (12)
Horiba Nobuaki,JPX ; Iwami Masaaki,JPX ; Shiomi Mitsuo,JPX, Die having protrusions for molding machine.
Soda Shigenari (Nagaokakyo JA) Hayashi Motoshige (Ikoma JA) Tanaka Shigetoshi (Nara JA), Method of forming a foamed article having a simulated wood grained surface.
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