A guiding element for a printing unit is provided to facilitate use of the printing unit in an imprinter function. In one operating situation, a strip is printed as it passes through a printing gap of the printing unit. In another operating situation, the strip is guided through the printing gap by
A guiding element for a printing unit is provided to facilitate use of the printing unit in an imprinter function. In one operating situation, a strip is printed as it passes through a printing gap of the printing unit. In another operating situation, the strip is guided through the printing gap by the guiding element in a non-contact manner. The guiding element includes, on the outer surface, a plurality of openings adapted for the discharge of a pressurized fluid. These openings are micro-openings of a diameter less than 500 μm.
대표청구항▼
What is claimed is: 1. A printing press comprising: at least a first printing unit including at least two cylinders defining a printing gap having an inlet area and an outlet area, said at least first printing unit being adapted for imprinter operation wherein in a first operational situation a web
What is claimed is: 1. A printing press comprising: at least a first printing unit including at least two cylinders defining a printing gap having an inlet area and an outlet area, said at least first printing unit being adapted for imprinter operation wherein in a first operational situation a web is imprinted in said printing gap and in a second operational situation the web is conducted without contact with said at least two cylinders in said printing gap; a first guide element in said inlet area and a second guide element in said outlet area; a wall of said at least second guide element, said wall including an outer surface having a surface area defining said guide element; and a plurality of outward-directed penetrating bores configured as micro-bores in said wall, each of said micro-bores having a diameter no greater than 500 μm, a density of said plurality of outwardly directed penetrating micro-bores per unit of said surface area being at least 0.2/mm2, said plurality of outwardly directed penetrating micro-bores being adapted for the exit of a fluid under pressure. 2. The printing press of claim 1 wherein each said guide element has a circular profile. 3. The printing press of claim 1 wherein each said guide element has a half-shell cross-sectional profile. 4. The printing press of claim 1 wherein each said guide element has a web-facing side having a cross-sectional profile in the shape of a segment of a circle. 5. The printing press of claim 4 wherein said segment of a circle extends over an angle of between 10�� and 45��. 6. The printing press of claim 4 wherein a width of said at least second guide element is between 30 and 150 mm. 7. The printing press of claim 1 wherein said diameter of said openings is not greater than 300 μm. 8. The printing press of claim 1 wherein said wall has a thickness of between 0.2 mm and 3.0 mm. 9. The printing press of claim 1 wherein said plurality of outward-directed penetrating micro-bores are adapted to discharge between 1 and 20 cubic meters of fluid per hour for each square meter of said surface. 10. The printing press of claim 9 wherein said fluid discharge rate is between 2 and 15 cubic meters of fluid per hour for each square meter of said surface. 11. The printing press of claim 1 further including a feed line adapted to feed fluid to said at least second guide element, said feed line having an interior diameter of less than 100 mm. 12. The printing press of claim 1 wherein each said guide element has an exterior diameter of between 60 and 100 mm. 13. The printing press of claim 1 wherein each said guide element has a length greater than 1,200 mm. 14. The printing press of claim 1 wherein said fluid under pressure is air. 15. The printing press of claim 1 wherein a portion of said at least second guide element is a releasable insert on a support defined by said wall. 16. The printing press of claim 15 wherein said wail has a profile which is matched to a path of travel of the web. 17. The printing press of claim 15 wherein said segment of a circle extends over an angle of between 10�� and 45��. 18. The printing press of claim 1 further including a second printing unit, one of said first and second printing units being adapted to print the web in a first mode of operation of the printing press while the web is conducted without contact through the other of said first and second printing units, and further where, in a second mode of operation, said one printing unit is disengaged from the web and the other of said first and second printing units is in contact with the web. 19. The printing press of claim 1 further including five printing units through which the web is conducted. 20. The printing press of claim 1 wherein said micro-bores are made by accelerated particles. 21. The printing press of claim 1 wherein said micro-bores are made by electron beams. 22. The printing press of claim 1 further including a dirt and ink repelling coating on at least said surface area of said at least second guide element. 23. The printing press of claim 22 wherein said coating is chromium. 24. The printing press of claim 23 wherein said surface area is polished to a high gloss. 25. A printing press comprising: at least a first printing unit including at least two cylinders defining a printing gap having an inlet area and an outlet area, said at least first printing unit being adapted for imprinter operation wherein in a first operational situation a web is imprinted in said printing gap and in a second operation situation the web is conducted without contact with said at least two cylinders in said printing gap; a first guide element in said inlet area and a second guide element in said outlet area; and a load bearing support of an at least partially fluid-permeable support material having a plurality of through-openings, said support material forming said at least second guide element, said at least partially-fluid permeable support material having an outer, non-supporting layer constituted as a micro-porous, air-permeable material having a plurality of micro-openings, said outer, non-supporting layer being located on said at least partially fluid-permeable support material and in fluid communication with said plurality of through openings in said support material in at least an outlet area of said second guide element which is adapted to be contacted by the web, said second guide element being formed as a hollow rod around which air flows. 26. The printing press of claim 25 wherein each said guide element has a circular profile. 27. The printing press of claim 25 wherein each said guide element has a half-shell cross-sectional profile. 28. The printing press of claim 25 wherein each said guide element has a web-facing side having a cross-sectional profile in the shape of a segment of a circle. 29. The printing press of claim 28 wherein said segment of a circle extends over an angle of between 10�� and 45��. 30. The printing press of claim 28 wherein a width of said at least second guide element is between 30 and 150 mm. 31. The printing press of claim 25 wherein said non-supporting outer layer having said plurality of micro-openings is adapted for the exit of fluid under pressure, each said micro-opening having a diameter of no greater than 500 μm. 32. The printing press of claim 31 wherein said micro-openings are open pores of a porous material. 33. The printing press of claim 32 wherein said pores have a mean diameter of 5 to 50 μm. 34. The printing press of claim 33 wherein said mean diameter is between 10 and 30 μm. 35. The printing press of claim 32 wherein said pores have a mean diameter of 5 to 50 μm. 36. The printing press of claim 35 wherein said mean diameter is between 10 and 30 μm. 37. The printing press of claim 32 wherein said non-supporting micro-porous material is an open-pored sinter material. 38. The printing press of claim 31 wherein said micro-openings of said non-supporting outer layer are adapted to discharge between 1 and 20 cubic meters of fluid per hour for each square meter of said surface. 39. The printing press of claim 38 wherein said fluid discharge rate is between 2 and 15 cubic meters of fluid per hour for each square meter of said surface. 40. The printing press of claim 31 further including a feed line adapted to feed fluid to said at least second guide element, said feed line having an interior diameter of less than 100 mm. 41. The printing press of claim 31 wherein each said guide element has an exterior diameter of between 60 and 100 mm. 42. The printing press of claim 31 wherein each said guide element has a length greater than 1,200 mm. 43. The printing press of claim 31 wherein said fluid under pressure is air. 44. The printing press of claim 25 wherein said non-supporting micro-porous material is an open-pored sinter material. 45. The printing press of claim 25 wherein said at least partially fluid-permeable support material has a support face supporting said outer non-supporting layer. 46. The printing press of claim 25 wherein said outer non-supporting layer has a thickness of less than 1 mm. 47. The printing press of claim 25 wherein said at least partially fluid-permeable support material has a plurality of unconnected fluid passages forming said through-openings and underlying said outer non-supporting layer. 48. The printing press of claim 25 wherein said load bearing support is a support tube with a hollow profile. 49. The printing press of claim 25 wherein a wall of said support material carries said outer, non-supporting layer, said wall a profile with a curvature adapted to a path of travel of the web. 50. The printing press of claim 49 wherein said wall of said support material has a curved profile in the shape of a segment of a circle. 51. The printing press of claim 50 wherein said segment of a circle extends over an angle of between 10�� and 45��. 52. The printing press of claim 50 wherein a width of said at least second guide element is between 30 and 150 mm. 53. The printing unit of claim 25 wherein said support material includes a wall having a thickness greater than 3 mm. 54. The printing press of claim 25 wherein said micro-openings constitute between 3% and 30% of said outlet area. 55. The printing press of claim 25 wherein said outer, non-supporting layer of said micro-porous material is charged with fluid at least 1 bar of excess pressure. 56. The printing press of claim 55 wherein said fluid has a pressure of at least 4 bar. 57. The printing press of claim 25 further including a second printing unit, one of said first and second printing units being adapted to print the web in a first mode of operation of the printing press while the web is conducted without contact through the other of said first and second printing units, and further where, in a second mode of operation, said one printing unit is disengaged from the web and the other of said first and second printing units is in contact with the web. 58. The printing press of claim 25 further including five printing units through which the web is conducted.
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이 특허에 인용된 특허 (24)
Hansen Robert E. (Clarendon Hills IL) Carlson H. L. (Chicago IL), Adjustable angle bar assembly for a printing press.
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